Indexes for the Proceedings

o

i

LAUR 93-2237

Indexes of

LD/t-u9-93-’4737c1#

d

the Proceedings

for the Nine Symposia

(Internationa~ on

Detonation

1951-89

..-“

Crane

Deal— .4 . —A–. ..”-*.=. -

x–

-, -,,Ramsay

-,.

Roach

Takala~.-. —..n. -. ..

.L. –— . ..’.

. . ‘..-:. . .~— .2%?-= -G-

-:*

,. ._-.

a.. = ,. , -,

—.,, ’..

w’=, . . . . .~,-. ,-— -

.+—.”. —.–

Los Akvnos iVatioJIdLaboratory

,...,.——

ABOUT THIS REPORT

This official electronic version was created by scanning the best available paper or microfiche copy of the original report at a 300 dpi resolution. Original color illustrations appear as black and white images. For additional information or comments, contact: Library Without Walls Project Los Alamos National Laboratory Research Library Los Alamos, NM 87544 Phone: (505)667-4448 E-mail: [email protected]

.

.

. .

INDEXES OFTHE PROCEEDINGSFOR THE NINE SYMPOSIA(INTERNATIONAL)ONDETONATION1951-89

S. L. CraneW. E. DealJ B. RamwyA. M. Ro(lch

B. E. Tmkda

.

. ..-’

.6

Los Ahmos National LaboratoryLOS A[(UI1OS, /viki 87545.

ABOUT THIS REPORT

This official electronic version was created by scanning the best available paper or microfiche copy of the original report at a 300 dpi resolution. Original color illustrations appear as black and white images. For additional information or comments, contact: Library Without Walls Project Los Alamos National Laboratory Research Library Los Alamos, NM 87544 Phone: (505)667-4448 E-mail: [email protected]

The Detonation Symposia

Number Date Location

1 11-12 January, 1951

2 9-11 February, 1955

3 26-28 September, 1960

4 12-15 October, 1965

5 18-21 August, 1970

6 24-27 August, 1976

7 16-19 June, 1981

8 15-19 July, 1985

9 27 August-1 September, 1989

10 12-16 July, 1993

Washington, District of Columbia

Washington, District of Columbia

Princeton, New Jersey

Silver Spring, Maryland, 1st International -

Pasadena, California .

Coronado, California

Annapolis, Maryland

Albuquerque, New Mexico

Portland, Oregon

Boston, Massaclmssetts

‘,

.

v

..

.

Contents

Section Page

Introduction . . . . . . . . . .

A.

B.

c.

D.

Titles Index . . . . . . ,

Topic Phrase Index . .

Author Index . . . . . . .

. . . . .

. . . . .

. . . . .

. . . . .

. .

. .

. .

,.

Acronym and Code Name Index

. .

. .

. .

. .

. .

. . . . 1

. . . . 3

. . . . 37

. . . . 93

. . . . 107

*

“

I

.

INDEXES OF THE PROCEEDINGS FORTHE NINE SYMPOSIA (INTERNATIONAL)

ON DETONATION, 1951-1989

Sharon L. Crane, William E. Deal,Alita M. Roach, and Bruce

INTRODUCTION

ABSTRACT

John B. Ramsay,E. Takala”

The Proceedings of the nine Detonation Symposia have becomethe major archival source of information of international researchin explosive phenomenology, theory, experimental techniques,numerical modeling, and high-rate reaction chemistry. In manycases, they contain the original reference or the only reference tomajor progress in the field. For some papers, the information ismore complete than the complementary article appearing in aformal journal; yet for others, authors elected to publish only anabstract in the Proceedings. For the large majority of papers, theSymposia Proceedings provide the only published reference to abody of work. This report indexes the nine existing Proceedings

of the Detonation Symposia by paper titles, topic phrases,authors, and frost appearance of acronyms and code names.

The indexes comprise four parts: (A) a Iisting ofthe paper titles and authors in order of appear-ance in each Symposium Proceedings, (B) analphabetical listing of topic phrases, (C) an index.of all authors, and (D) an index to first appear-ance of acronyms and code names of composi-tions and components that are defined.

Each index also lists the Symposium number andpage number of the reference. These are theactual page numbers of the original Proceedings

of the Fourth through the Ninth Symposia. thepage nuuibers shown for the First and SecondSymposia are for the single combined volumereprinted by the Detonation Symposium Commit-tee in 1987 (NSWC MP 87-194), and not theoriginal page numbers. Some confusion alsoexists for references from the Third Symposiumin that it was initially published as three paper-back volumes. These were combined into asingle hardbound volume, identified by thepublisher, The OffIce of Naval Research. U. S,Navy, as ACR-52, The page numbers used inthese Indexes for the Third Symposium are thosefrom this latter publication.

* Major, US Amly

A. TITLES INDEX

In this first index, the chronological order of thepapers is preserved, beginning with the FirstSymposium and the first paper presented. Welist the Symposium number, page number, papertitle, co-authors, and nation of the first author.

B. TOPIC PHRASE INDEX

Here we list topic phrases alphabetically withreference to the Symposium number and pagenumber. We considered using key words, whichare cryptic and more mnemonic, rather than thelonger and more descriptive topic phrases, butwe decided on the latter because they providemore information for selecting the correct refer-ence. The compilers have used their own judg-ment in selecting and defining the topic phrasesand hope that the phrases are self-explanatory.At the present time, a significant cross-referenc-ing capability is lacking within the index, andusers are cautioned to check several different

‘ possible topics when searching.

We note that a different co-author selected thetopic phrases for the Ninth than for the earlierSymposia. Hence, a difference in personal stylemay be apparent. A quantifiable difference isthe 8.9 citations per paper for the Ninth and 7.2for the earlier Symposia. Another difference isthat all page references for the Ninth Symposiumare to the first page of the paper, rather than tothe page where the topic phrase appears.

C. AUTHOR INDEX

This index is a simple listing of all authors,giving the Symposium number and page numberreferences. All except family names werecontracted to initials. We have attempted tocombine different presentations of an author’sname (e.g., J. Ramsay and J. B. Ramsay) into aunifoml entry. Please notify the compilers ofany errors.

D. ACRONYM AND CODE NANIEINDEX

This index is an attempt to cite the first use ofan acronym or code name for neat explosives,ingredients, and formulations, for which a defini-tion of the term is also provided. The names ofsome explosive compositions that were ‘“knownto evexyone” in 1950 are no longer in commonusage, particularly within the international com-munity. For example, the names MEDINA andDfNA were used in at least one instance with norecognized chemical name or fomlula given.Rather interestingly, no definition of RDX \vmlocated within the Proceedings until the FifthSymposium.

Many explosive compounds and compositionsare named as a contraction of the chemical name(e.g., TNT); for others, the history of the nameis lost in research laboratories (e.g, HMX”- ); andothers have no relationship to the composition(e.g., X-0290).

A large number of papers within the SymposiaProceedings refer to compositions only by acro-nym or code name, with no formal definition ofcomposition. Composition B (Comp B) is citedin many papers, yet at least 10 citations forComposition B provide similar but differentcompositions. Also, in some instances, the smneexplosive compound was defined by three ormore different acronyms.

We intended that each citation be the earliestreference within the nine Proceedings to the useof the acronym coupled with a meaningfulchemical -definition. Errors in finding andentering thb citations may have occurred. Ifreaders detect errors, please contact one of theauthors.

** Ray Walker has told JBR that HMX mostprobably stands for High Melting e~losive, butWalker has also heard a reasonable statementthat the initials may have been derived from~olston ~ilitary efilosive. [t does not stand for& Majesty’s e~losive.

A. Titles IndexBy Symposium and Page

Sy. Pg Title, Authors, Country

1.0003

1.0009

1.0012

1.0022

1.0031

1.0039

1.0043

1.0045

1.0052

1.0057

1.0071

1.0072

1.0079

1.0088

1.0093

1.0105.1.01072.0119

s2.0136

2.0151

2.0157

2.0168

2.0187

2.0198

2.0216

2.0231

2.0251

2.0266

2.0281

2.0295.

.)

Recent Studies in BURORD, S. Brunauer, USA

Recent Work on Detonation at Aberdeen, J. M. Dewey, USA

Studies on Detonation Phenomena, F. C. Gibson and C. M. Mason, USA

Recent Work at NOL, D. Price, USA

Recent Studies at the Naval Ordnance Test Station, J. S. Rinehart, USA

Some Recent Studies in Canada, G. R. Walker, Canada

Chemical Aspects of Detonation, B. Lewis, USA

Nonstationary Detonation Waves in Gases, G. B. Kistiakowsky, USA

Duration of the Reaction in a Detonating Explosive, S. J. Jacobs, USA

Experiments on the Transition from Deflagration to Detonation, J. Roth, USA

Physical Aspects of Detonation, J. G. Kirkwood, USA

The Equation of State for Detonation Gases, S. R. Brinkley, USA

Convergent Shock Waves, A. Kantrowitz, USA

Shock Waves in Solids, J. E. Ablard, USA

Interactions of Detonation Waves with Material Boundaries, R. B. Parlin and H. Eyring, USA

Problems and Future Developments, G. B. Kistiakowsky, USA

Theoretical Developments in Detonation, J. G. Kirkwood, USA

Charge Preparation for Precise Detonation Velocity Studies, E. James, USA

Technique for the Measurement of Detonation Velocity, A. W. Campbell, M. E. Malin,

T. J. Boyd, and J, A. Hu1l, USA

A Microwave Technique for Measuring Detonation Velocities, T. J. Boyd, P. Fagan, USA

Measurement of Detonation Temperatures, F. C. Gibson, M. Bowser, C. R. Summers,

F. H. Scott, J. C. Cooper, and C. M. Mason, USA

A New Cine Microscope and its Application to Detonation Phenomena, J. S. Courtney-Pratt,

UK

The Measurement of Density Changes in Gaseous Detonations, G. B. Kistiakowsky, and

P. H. Kydd, USA

The Attainment of Thermodynamic Equilibrium in Detonation Waves, G. B. Kistiakowsky

and W. G. Zinman, USA

On the Structure of a Detonation Wave, W. R. Gilkerson and N. Davidson, USA

High Temperature Thermodynamic and Gaseous Detonations in Mixtures of Cyanogen,

Oxygen, and Nitrogen, H. M. Peek and R. G. Thrap, USA

Detonation in Gases at Low Pressure, A. L. Bennet and H. W. Wedaa, USA

Measurements on Gaseous Detonation Waves, J. A. Nicholls, R. B. Morrison, and

R. E.Culled, USA

Studies on Gaseous Detonation, B. Greifer, F. C. Gibson, and C. M. Mason, USA

Condensation Shocks and Weak Detonations, S. G. Reed, and W. H. Heybey, USA

.

A. Titles Index (Continued)

Sy.Pg Title, Authors, Country

2.0312

2.0327

2.0343

2.0358

2.0383

2.0404

2.0424

2.0439

2.0454

2.0478

2.0500

2.0519

2.0529

2.0547

2.0561

2.0571

2.0582

2.0601

2.0612

2.0620

2.0643

2.0695

2.0711

2.0733

2.0749

The Structure of a Steady-State Plane Detonation Wave with Finite Reaction Rate,

J. G. Kirkwood and W. W. Wood, USA

The Measurement of Chapmrm-Jouguet Pressure for Explosives, W. E. Deal, USA

Measurement of the Chapman-Jouguet Pressure and Reaction Zone Length in a Detonating

High Explosive, R. E, Duff and E. Houston, USA

The Detonation Zone in Condensed Explosives, H. D. Mallow and S. J. Jacobs, USA

Calculation of the Detonation Properties of Solid Explosives with the Kistiakowsky-Wilson

Equation of State, W. Fickett and R. D. Cowan, USA

A Solid-State Model for Detonations, R. B. Parlin and J. C. Giddings, USA

Diameter Effect in Condensed Explosives. The Relation Between Velocity and Radius of

Curvature of the Detonation Wave, W. W. Wood and J. G. Kirkwood, USA

The Detonation Behavior of Liquid TNT, E. A. Igel and L. B. Seely, USA

Detonation in Homogeneous Explosives, A. W. Campbell, M. E. Malin, and T. E. Holland,

USA

Particle Size Effects in One- and Two-Component Explosives, M. E. Malin, A. W. Campbell,

and C. W. Mautz, USA

Detonation Wave Fronts in Ideal and Non-Ideal Detonation, M. A. Cook, USA

Detemlination of Reaction Rate of Sodium Nitrate and the Equation of State of 50/50

TNT-NaN03 , M. A. Cook and W. O. Ursenbach, USA

The Decomposition of A1pha-Lead Azide, J. M. Groocock, UK

The Detonation of Azides by Light, J. S. Courtney-Pratt and G. T. Rogers, UK

Detonation in Azides when the Dimensions Are Comparable with the Length of the Reaction

Zone, F. P. Bowden and A. C. Mclaren, UK

Origin of Luminosity in Detonation Waves, E. Jones, UK

The Role of Gas Pockets in the Propagation of Low Velocity Detonation, O. A. J. Gurton,

UK

Sensitiveness to Detonation, E. Jones and 1. G. Cumming, UK

Initiation of Military Explosives by Projectile Impact, J. M. Dewey, USA

Factors Affecting the Transmission of Detonation Behveen Small Explosive Charges,

I. D. Hampton, J. Savitt, L. E. Starr, and R. H. F. Stresai, USA

The Correlation of the Sensitiveness of Explosives with Combustion Data, E. G. Whitbread

and L. A. Wiseman, UK

Problems of Initiation in Tests of Sensitiveness, E. G. Whitbread, UK

Lead Azide Precipitated with Polyvinyl Alcohol, T. G. Blake, D. E. Seegar, and

R. H. F. Stresau, USA

Thermo-Hydrodynamics and the Reaction Kinetics in Some Metalized Explosives,

M. A. Cook, A. S. Filler, R. T. Keyes, W. S. Partridge, and W. O. Ursenbach, USA

Conditions Behind the Reaction Zone of Confined Columns of Explosive--Notions Derived

from Plate Dent Experiments, W. M. Slie, and R. H. F. Stresau, USA

w

.

.



3.0001

3.0010

3.0024

3.0042

3.0050

3.0060

3.0077

3.0088

3.0112

3.0120

3.0139

3.0150

3.0184

. . 3.0202

3.0205

*3.0226

3.0241

3.0253

3.0267

3.0285

3.0304

3.0309

3.0327

3.0357

3.0386

3.0396

A Colliding Ball High Explosive Impact Sensitivity Testing Machine, C. M. Bean, G. P.

Cachia, and J. Kirkham, UK

A Photographic Study of Explosions Initiated by Impact, J. Wenograd, USA

Pure Environmental Shock Testing of Condensed Phases, T. A. Erikson, USA

On the Memory Effect in the Thermal Initiation of Explosives, W. R. Hess, and R. C. Ling,

USA

The Thermal Decomposition of [C O(NH3)6 ](N3)3 , T. B. Joyner, and F. H. Verhoek, USA

The Behavior of Explosives at Very High Temperatures, J. Wenograd, USA

The Rapid Burning of Secondary Explosives by a Convective Mechanism, J. W. Taylor, UK

Electrical Initiation of RDX, G. M. Muller, D. B. Moore, and D. Bernstein, USA

Detonation Studies in Electric and Magnetic Fields, F. E. Allison, USA

Electrical Measurements in Detonating Pentolite and Composition B, R. L. Jameson, USA

On the Electrical Conductivity of Detonating High Explosives, B. Hayes, USA

Ionization in the Shock Initiation of Detonation, R. B. Clay, M. A. Cook, R. T. Keyes,

O. K. Shupe, and L. L. Udy, USA

Chemical Factors in External Detonation-Generated Plasmas, M. A. Cook and A. G. Funk,

USA

Detonation Plasma, R. T. Keyes, E. L. Kendrew, and E. G. Whitbread, UK

Energy Transfer to a Rigid Piston under Detonation Loading, A. K. Aziz, H. Hurwitz, and

H. M. Steinberg, USA

A Computer Program for the Analysis of Transient Axially Symmetric Explosion and Shock

Dynamics Problems, T. Orlow, D. Piacesi, and H. M. Steinberg, USA

Pressure Profiles in Detonating Solid Explosive, G. E. Hauver, USA

Decay of Explosively-Induced Shock Waves in Solids and Spallings of Aluminum,

J. O. Erkman, USA

Effects of Boundary Rarefactions on Impulse Delivered by Explosive Charge, B. C. Taylor,

USA

Experimental Determination of Stresses Generated by an Electric Detonator, J. S. Rinehart,

USA

Comments on Hypervelocity Wave Phenomena in Condensed Explosives, R. F. Chaiken,

USA

Nonideal Detonation of Ammonium Nitrate-Fuel Mixtures, L. D. Sadwin, R. H. F. Stresau,

and J. Savitt, USA

The Detonation Velocity of Pressed TNT, M. J. Urizar, E. James, and L. C. Smith, USA

Measurement of Detonation, Shock, and Impact Pressures, R. T. Keyes, and

W. O. Ursenbach, USA

Low Pressure Points on the Isentropes of Several High Explosives, W. E. Deal, USA

Strong Shocks in Porous Media, J. L. Austing, H. S. Napadensky, R. H. F. Stresau, and

J. Savitt, USA



.

w

3.0420

3.0436

3.0455

3.0469

3.0499

3.0520

3.0534

3.0562

3.0574

3.0584

3.0606

3.0635

3.0659

3.0671

3.0693

3.0706

3,0721

3.0725

3.0738

3.0761

3.0784

3.0813

3.0822

6

The Behavior of Explosives at Impulsively Induced High Rates of Strain, H. S. Napadensky,

R. H. F. Stresau, and J. Savitt, USA

Initiation and Growth of Detonation in Liquid Explosives, F. C. Gibson, C. R. Summers,

C. M. Mason, and R. W. Van Dolah, USA

Initiation Characteristics of Mildly Confined, Bubble-Free Nitroglycerine, C. H Winning,

USA

Shock Initiation of Detonation in Liquid Explosives, A. W. Campbell, W. C. Davis, and

J. R. Travis, USA

Shock Initiation of Solid Explosives, A. W. Campbell, W. C. Davis, J. B. Ramsay, and

J. R. Travis, USA

Shock Induced Sympathetic Detonation in Solid Explosive Charges, M. Sultanoff,

V. M. Boyle, and J. Paszek, USA

Growth of Detonation from an Initiating Shock, J. W. Enig, USA

Initiation of a Low-Density PETN Pressing by a Plane Shock Wave, G. E. Seay and

L. B. Seely, USA

The Transition from Shock Wave to Detonation in 60/40 RD2UTNT, E. L. Kendrew, and

E. G. Whitbread, USA

Determination of the Shock Pressure Required to Initiate Detonation of an Acceptor in the

Shock Sensitivity Test, I. Jaffe, R. Beauregard, and A. B. Atnster, USA

A Computational Treatment of the Transition from Deflagration to Detonation in Solids,

C. T. Zovko and A. Macek, USA

A Method of Determination of Detonability of Propellants and Explosives, S. Wachtell and

C. E. McKnight, USA

Sensitiveness Testing and its Relation to the Properties of Explosives, E. G. Whitbrerid, UK

Sensitivity Relationships, M. J. Kamlet, USA

A Statistical Correlation of Impact Sensitivity with Oxygen Balance for Secondaxy

Explosives, J. Alster, USA

The Electric-Spark Initiation of Mixtures of High Explosives and Powdered Electrical

Conductors, T. P. Liddiard and B. E. Drimmer, USA

Detonation Wd Shock Review, M. L. Wilkins, USA - ‘

Detonation Performance Calculations Using the Kistiakowsky-Wilson Equation of State,

C. L. Mader, USA

Energy Release from Chemical Systems, J. W. Kuxy, G. D. Dorough, and R. E. Sharples,

USA

The Detonation Properties of (1 ,3-Dianlino, 2,4,6 -Trinitrobenzene), N.

B. E. Drimmer, and T. P. Liddiard, USA

Non-Steady Detonation - A Review of Past Work, S. J. Jacobs, USA

L. Colebum,

The Shock Initiation of Detonation in Liquid Explosives, W. A. Gey and K. Kinaga, USA

Sensitivity of Propellants, W. W. Brandon and K. F. Ockert, USA

.

●



3.0833

3.0842

4.0003

4.0014

4.0027

4.0039

4.0047

4.0052

4.0067

4.0078.

4.0084

●

4.0086

4.0092

4.0096

4.0102

4.0107

4.0117

4,0126

4.0135

4.0142

4.0153

Some Studies on the Shock Initiation of Explosives, E. N. Clark and F. R. Schwartz, USA

The Influence of Energy on the Decomposition of the Transition from

Initiation to Detonation, Z. V. Harvalik, USA

Metal Acceleration by Chemical Explosive, J. W. Kury, H. C. Homig, E. L. Lee,

J. L. McDonnel, D. L. Omellas, M. Finger, F. M. Strange, and M. L. Wilkins, USA

The Motion of Plates and Cylinders Driven by Detonation Waves at Tangential Angles,

N. E. Hoskin, J. W. S. AlIan, W. A. Bailey, J. W. Lethaby, and I. C. Skidmore, UK

The Chapman-Jouguet Isentrope and the Underwater Shock Wave Performance of Pentoiite,

W. A. Walker and H. M. Steinberg, USA

Detonation of a Cylindrical Charge-Study of the Flow of Burned Gases, C. Fauquignon,

M. Prouteau, and G. Verdes, France

The Equation of State of Detonation Products Behind Overdriven Detonation Waves in

Composition B, I. C. Skidmore and S. Hart, UK

An Equation of State of Detonation Products at Pressure below 30 Kilobars, J. W. S. AlIan

and B. D. Lamboum, UK

Structure, Chemistv, and Instability of Detonation in Gases, G. L. Schott, USA

Theoretical Considerations on the Propagation of Shock and Detonation Waves, R. Cheret,

France

Failure of the Chapman-Jouguet Theory for Liquid and Solid Explosives (Abstract Only),

W. C. Davis, B. G. Craig, and 3. B. Ramsay, USA

Radius of Curvature Effect on Detonation Velocity, L. G. Green and E. James, USA

Lateral Shock Pressure Measurements at an Explosive Column, L. D. Sadwin and

N. M. Junk, USA

Studies on the Diameter-Dependence of Detonation Velocity in Solid Composite Propellants:

I. Attempts to Calculate Reaction-Zone Thickness, M. L. Pandow, K. F. Ockert, and

H. M. Shuey, USA

Studies of the Diameter-Dependence of Detonation Velocity in Solid Composite Propellants:

II. Prediction of Failure Diameter, M. L. Pandow, K. F. Ockert, and T. H. Pratt, USA

Non-Ideal Detonation with Constant Lateral Expansion, F. Wecken, France

Detonations in Liquid Explosives - The Low Velocity Regime, R. W. Watson,

C. R. Summers, F. C. Gibson, R. W. .Van Dolah, USA

Detonation of Nitromethane-Tetranitromethane Mixtures: Low and High Velocity Waves,

A. B. Amster, D. M. McEachem, and Z. Pressman, USA

Observation and Study of the Conditions for the Formation of Mach Detonation Waves,

J. P. Argous, C. Peyre, and J. Thouvenin, France

Mach Interaction of T\vo Plane Detonation Waves, B. D. Lamboum and P. W. Wright, UK

Interaction of Oblique Detonation Waves with Iron (Abstract Only), H. M. Steinberg and

D. Piacesi, USA.

w

7



4.0154

4.0156

4,0167

4,0168

4.0176

4.0179

4.0198

4.0203

4.0213

4.0214

4.0222

.4.0233

4.0239

4.0240

4.0241

4.0248

4.02584.0266

4.02774.0289

4.0290

4,0295

4.0305

Interactions of Detonation Waves in Condensed Explosives (Abstract Only), S. D. Gardner

and J. Wac!ierle, USA

Axial Initiation of Multi-Component Explosives Charges, L. Deffet and C. Fosse, Belgium

A Detonation Calorimeter and the Heat of Products of Detonation of Penta-Erythritol

Tetranitrate (PETN) (Abstract Only), D. L. OmeIlas, J. H. Carpenter and S. R. Gunn, USA

Anomalous Isentrope Results Obtained with the RUBY Computer Program, J. Hershkowitz,

USA

Front and Mass Veloci~ at Detonation in Evacuated Chambers, M. Lundborg, Sweden

Detonation Limits in Condensed Explosives, W. E. Gordon, USA

Summary of Papers on Condensed Phase Detonation, R. E. Duff, USA

Evaluation of the Griineisen Parameter for Compressed Substances: I. Metals,

W. H. Andersen, USA

The Equation of State of 1060 Aluminum from Shock Wave Measurements (Abstract Only),

G. D. Anderson, A. L. Fahrenbruch, and G. R. Fowles, USA

The Compression of Polymethyl Methacrylate by Low Amplitude Shock Waves,

T. P. Liddiard, USA

Shock Wave Compression of Plexiglas from 3 to 20 Kilobars, W. J. Halpin and

R. A. Graham, USA

Analysis of Shock Wave and Initiation Data for Solid Explosives, J. B. Ramsay and

A. Popolato, USA

Low-Pressure Hugoniots of Solid Explosives (Abstract Only), R. J. Wasley and J. F. O’Brien,

USA

The Unreacted Hugoniot Equations of State of Several Explosives (Abstract Only),

N. L. Colebum and T. P. Liddiard, USA

Determination of Shock Hugoniots for Several Condensed Phase Explosives, V. Boyle,

R. L. Jameson, and M. Sultanoff, USA

Shock Induced Phase Transitions, G. E. Duvall and Y. Horie, USA

Effect of a Shock Wave on a Porous Solid, J. Thouvenin, France

Shock Behavior of Some Non-Reacting Porous Solids, J. R. Rempel and D. N. Schmidt, USA

Elastoplastic Effects in the Attenuation of Shock Waves: ~J.O. Erkman, USA

Hydrodynamic Elastic Plastic Theoxy and Plane Shock Waves in Metals: I. Theory

(Abstract Only), J. C. Pearson, USA

The Elasto-Plastic Release Behavior of Magnesium at 80 kb, P. J. A. Fuller and J. H. Price,

UK

The Influence of Mechanical Properties on Wave Propagation in Elastic-Plastic Materials,

B. M. Butcher and D. E. Munson, USA

The Instability of an Interface Between Two Fluids under Variable Normal Acceleration,

1. G. Cameron and H. H. M. Pike, UK

.



4.0316

4.0321

4.0349

4.0359

4.0373

4.0381

4.0386

4.0394

4.0395

4.0399. 4.0404

4.0412

.4.0426

4.0432

4.0435

4.0442

4.0449

4.0461

4.0462

4.0473

4.0477

4.0487

4.0496

4.0502

4.0512

Calculation of the Growth of Interface Instabilities by a Lagrangian Mesh Method,

L. A. Elliot, UK

Shock Wave Research on Inert Solids, W. E. Deal, USA

The Effect of Interstitial Gas on the Shock Sensitivity of Lo\v Density Explosive Compacts.

M. C. Chick, UK

Shock Initiation of Low-Density Pressings of Ammonium Perchlorate, M. W. Evans,

B. O. Reese, and L. B. Seely, USA

Initiation of a Solid Explosive by a Short-Duration Shock, E. F. Gittings, USA

Oblique Impact of a Layer of Explosive by a Metal Plate, F. David, C. Fauquignon,

H. Bemier, and J. Potau, France

Experimental Observations of Initiation of Nitromethane by Shock Interactions at

Discontinuities, J. R. Travis, USA

Initiation of Detonation by the Interaction of Shock with Density Discontinuities (Abstract

Only), C. L. Mader, USA

An Equation of State and Derived Shock Initiation Criticality Conditions for Liquid

Explosives (Abstract Only), J. W. Enig and F. J. Petrone, USA

The Effect of Wax on the Shock Sensitivity of Explosive Compacts, J. Eadie, UK

Direct Contact Detonation Sensitivity, J. Savitt, Capt. N. Leone, and C. Kyselka, USA

The Effect of Physical and Chemical Properties on the Sensitivity of Liquid Explosives,

J. E. Hay, J. Ribovich, F. H. Scott, and F. C. Gibson, USA

Resonation Caused by the Reflection of Divergent Waves, W. R. Marlow, UK

Comparison Behveen Shooting and Barrier Tests, N. Lundborg, Sweden

The Initiation Properties of Boosters in Explosives with Low Sensitivity, C. H. Johansson and

T. Sjolin, Sweden

Size Factors in Detonation Transfer, R. H. F. Stresau, USA

Confinement Effects in Exploding Bridgewire Initiation of Detonation, R. H. F. Stresau,

R. M. Hillyer, and J. E. Kennedy, USA

Surface Rate Pocesses and Sensitivity of High Explosives (Abstract Only), R. F. Chaiken and

F. J. Cheselske, USA

Low Order Reactions in Shocked Explosive, N. Griffiths ‘and V. C. Broom, UK

Initiation of Explosives by Low Velocity Impact, H. S. Napadensky, USA

Further Studies on the Ignition of Explosives, L. G. Green and G. D. Dorough, USA

The Initiation of Burning in High Explosives by Shock Waves, T. P. Liddiard, USA

Mechanical and Detonation Properties of Rubber Bonded Sheet Explosives, W. Kegler and

R. Schall, France

Explicit Solutions for Unsteady Shock Propagation in Chemically Reacting Media,

G. K. Adams and M. Cowperthwaite, UK

Summaxy Paper on Initiation, Ignition and Growth of Reaction, G. P. Cachia, UK

.



4.0519

4.0527

4.0538

4.0555

4.0566

4.0573

4.0584

4.0595

4.0602

4.0609

4.0616

4.0627

4.0639

5.0003

5.0013

5.00315.0034

5.0041

5.0047

5.0059

5.0067

The Use of One- and Two-D inlensional Hydrodynamic Machine Calculations in High

Explosive Research, M. L. Wilkins, USA

Calculation of Unsteady 2-D Flows by Various Numerical Methods, A. Vidart, P. Beatrix,

Y. Chevalier, and H. Bouchon, France

The Calculation of Hydrodynamic Behavior of Plane One Dimensional Explosive/Metal

Systems, B. D. Lamboum and J. E. Hartley, UK

A Method for the Study of Properties of Solid Explosives and Other Solid (Including Porous)

Materials when Subjected to Shock Waves, W. L. Murry and J. Plant, UK

Experimental Method for the Analysis of the Structure of a Shock Wave in a Solid, C. Peyre,

J. Pujol, and J. Thouvenin, France

A Technique for the Precise Measurement of the motion of a Plane Free Surface, G. Eden

and P. W. Wright, UK

A Microwave Technique for Studying Detonation Phenomena, E. G. Johnson, USA

On Electrical Conductivity in Detonation Products, P. Hayes, USA

A Technique for Detailed Time-Resolved Radiation Measurements in the Reaction Zone of

Condensed Explosives, P. -A. Persson, B. Andersson, and S. O. Stahl, Sweden

Electrical Transducer Studies of Initiation of Liquid Explosives, J. R. Travis, USA

Electrical Probe Technique for Measurement of Detonation and Deflagration Velocities,

L. D. Pitts, USA

Anomalous Thermoelectric Effect in the Shock Regime and Application to a Shock Pressure

Transducer, J. Crosnier, J. Jacquesson, and A. Migault, France

PHERMEX Applications to Studies of Detonation Waves and Shock Waves, D. Venable and

T. J. Boyd, USA

Flash X-Ray Obsemation of Marked Mass Points in Explosive Products, W. C. Rivard,

D. Venable, W. Fickett, and W. C. Davis, USA

Pressure Measurements for Composition B-3, W. C. Davis and D. Venable, USA

Divergent Spherical Detonation Waves in a Solid Explosive, R. Cheret and G. Verdes, France

Shock Velocity Measurements in Inert Monitors Placed on Several Explosives, R, L. Jameson

and A. Hawkins, USA

A Comparison of Spherical, Cylindrical and Plane Detonation Velocities in Sorue Condensed

and Gaseous Explosives, C. Brochet,. J. Brossard, N. Manson, R. Cheret, and G. Verdes,

France

Detonation Characteristics of Very Low Density Explosive Systems, J. L. Austing,

A. J. Tulis, and C. D. Johnson, USA

An Analysis of the “Aquariunl Technique” as a Precision Detonation Pressure Measurement

Gage, J. K. Rigdon and I. B. Akst, USA

Effects of Precompression upon the Detonation Properties of Liquid and Solid Explosives.

W. H. Andersen, L. Zemow, A. L. Mottet, and R. R. Randall, USA

.

v

.

●

.

.10



5.0081

5.0089

5.0099

5.0105

5.0115

5.0119

5.0137

5.01535.0169

5.0177

5.0185

. 5.0191

5.0207

5.0219

5.0231

5.0237

5.0247

5.0251

5.0259

3.0267

5.0279

3.0291

3.0301

The Stability of Low-Veloci~ Detonation Waves, R. W. Watson, J. Ribovich, J. E. Hay, and

R. W. Van Dolah, USA

Failure Diameter, Sensitivity and Wave Structure in Some”Bis-Difluoroamino Alkanes,

L. B. Seely, J. G. Berke, R. Shaw, D. Tegg, and M. W. Evans, USA

The Failure Diameter Theory of Dremin, J. W. Enig and F. J. Petrone, USA

Wall Traces of Detonation in Nitromethane-Acetone Mixtures, P. A. Ufiiew and

A. S. Kusabov, USA

A Photographic Technique for Mapping Failure Waves and Other Instability Phenomena in

Liquid Explosives Detonation, P. -A. Persson and G, Bjamholt, Sweden

On the Dynamics of Shock Interactions, A. K. Oppenheim, J. J. Smolen, D. Kwak, and

P. A. Urtiew, USA

Metal Acceleration by Composite Explosives, M. Finger, H. C. Homig, E. L. Lee, and

J. W. Kuxy, USA

Light Emission during Initiation of Liquid Explosives, P. -A. Persson, and T. Sjolin, Sweden

Dark Waves in Liquid Explosive Systems: Their Role in Detonation Failure,

R. W. Watson, USA

Numerical Calculations of Detonation Failure and Shock Initiation, C. L. Mader, USA

The role of the Matrix in Determining the Shock Initiation Characteristics of Compositions

Containing 60% by Volume of HMX, W. W. Marshall, UK

Effect of Pulse Duration on the Impact Sensitivity of Solid Explosives, B. D. Trott and

R. G. Jung, USA

Shock Sensitivity, a Property of Many Aspects, D. Price, USA

Shock Sensitivity and Shock Hugoniots of High-Density Granular Explosives, J. Roth, USA

Experimental Study of the Transition from Burning to Detonation, J. ‘Calzia, and H, Carabin,

France

Shock Initiation of Nitromethane, Methyl Nitrite, and Some Bis Difluoro Alkanes,

J. G. Berke, R. Shaw, and L. B. Seely, USA

The Role of Interstitial Gas in the Detonation Build-up Characteristics of Low Densi@

Granular HMX, W. W. Marshall, UK

The Shock Hugoniot of Unreacted Explosives, V. M. Bo~le, W. G. Smothers, and

L. H. Ervin, USA

Effect of Particle Size on Shock Initiation of PETN, RDX, and Tetryl, C. L. Scott, USA

Explosive Behavior of Methylnitrate and its Mixtures with Liquid Diluents, M. Kusakabe and

S. Fujiwara, Japan

The Therm al Initiation and Growth of Reaction in Secondary Explosives under Transient

Confinement, K. Beedham, A. S. Dyer, and W. I. Holmes, UK

Initiation of Detonation by Friction on a High Explosive Charge, A. S. Dyer and

J. W. Taylor, UK

Deflagration in Single Cystals of Lead Azide, M. M. Chaudhri and J. E. Field, UK

II



.

r

5.0311

5.0313

5.0321

5.0331

5.0339

5.0351

5.0361

5.0369

5.0387

5.0399

5.0403

5.0413

5.0427

5.0429

5.0435

5.0447

5.0457

5.0467

5.0477

5.0487

5.0493

5.0501

The Influence of Surface Melting of Crystals on the Burning of Solid Explosive under Rising

Pressure Conditions (Abstract Only), J. W. Taylor, UK

Deformation of a Cylinder of Explosive Material in Unconfined Impact, H. S. Napadensky,

T. V. Eichler, C. A. Kot, and T. A. Zaker, USA

Decomposition of a Shocked Solid Explosive, B. G. Craig and E. F. Marshall, USA

Thermal Decomposition of High Explosives at Static Pressure 10-50 Kilobars, E. L. Lee,

R. H. Sanbom, and H. D. Stromberg, USA

Experimental Observations of Initiation of Primary Explosives by a Hot Wire, H. S. Leopold,

USA

Equation-of-State Investigation of Granular Explosives Using a Pulsed Electron Beam,

J. H. Shea, A. Mazzella, and L. Avrami, USA

Creation of an Intense Shock in Solid Deuterium by a Pulsed Laser Beam, C. Fauquignon,

France

Quartz Gauge Technique for hnpact Experiments, G. E. Ingram and R. A. Graham, USA

Shock-Induced Electrical Signals from Dielectrics, G. E. Hauver, USA

The Mechanism of Electrical Conductivity of Liquid Dielectrics in Shock Waves,

A. N. Dremin and V. V. Yakushev, USSR

Electrical Effect of Bimetallic and Metal Semiconductor Junctions Under Shock,

J. Jacquesson, J. P. Remain, M. Hallouin, and J. C. Desoyer, France

Experimental Study of the Electromagnetic Velocity-Gage Technique, S. J. Jacobs and

D. J. Edwards, USA

Detennination of Constitutive Relationships with Multiple Gages in Non-Divergent Waves,

M. Cowperthwaite and R. F. Williams, USA

Shock-Induced Electrical Polarization of a Solid Explosive, J. Morvan and H. Pujols, France

Quartz Gauge Study of Upstream Reaction in a Shocked Explosive, J. E. Kennedy, USA

Measurement of Mass Motion in Detonation Products by an Axially-Symmetnc

Electromagnetic Technique, B. Hayes and J. N. Fritz, USA

Explosive Deflection of a Liner as a Diagnostic of Detonation Flows, M. Defoumeaux and

L. Jacques, France

Elastic-P1astic. Behavior of Porous Bexyllium, G. Eden, C. P. M. Smith, UK

Numerical Analysis of a Diverging Sl~ock Wave in Plexiglas Cylinders, M. Kamegai and

J. O. Erkman, USA

A Code Method for Calculating Hydrodynamic Motion in HE Detonations, C. E. Needham,

USA

A Realistic Approach for Describing the Explosion-Generated Axi-Symmetric Wave

Propagating in a Half-Space, A. Sakurai, USA

The Computation of General Problems in One Dimensional Unsteady F1OWby the Method of

Characteristics (Abstract Only), B. D. Lamboum and N. E. Hoskin, UK

.

●

.



5.0303

5.0513

5.0323

3.0533

5.0547

3.0539

5.0567

3.0573

3.0581

5.0589

3.0597

. 3.0599

6.0003n

6.0011

6.0020

6.0029

6.0036

6.0047

6.0062

6.0068

6.0076

6.0105

6.0115

6,0124.

.

Equation of State of Detonation Products, H. C. Homig, E. L. Lee, M. Finger, and

J. E. Kurrle, USA

Optical Properties of Detonation Waves (Optics of Explosives), M. Busco, Italy

Hydrodynamic Behavior and Equation of State of Detonation Products Below the

Chapman-Jouguet State, L, A. Roslund and N. L. Colebum, USA

Shocked States of Four Overdriven Explosives, J. H. Kineke and C. E. West, USA

Vaporization of Uranium after Shock Loading, P. de Beaumont and J. Leygonie, France

Observations of Detonation in a High Vacuum, J. E. Hay, W. C. Peters, and R. W. Watson,

USA

Plane Spalling of Copper, F. David, J. Vacellier, F. Prouteau, J. Legrand, and R. Cheret,

France

Spalling under Oblique Impact, I. C. Skidmore and J. W. Lethaby, UK

Interactions of Spherical Shock Waves in Water, N. L. Colebum and L. A. Roslund, USA

The Speed of Propagation of Release Waves in Polymethyl Methacrylate, K. W. Schuler,

USA

Artificial Viscosity Method Calculation of an Underwater Detonation, H. M. Steinberg and

W. A. Walker, USA

Spherical Explosions in Water, L. W. Hantel and W. C. Davis, USA

Separation of Ignition and Buildup to Detonation in Pressed TNT, B. C. Taylor and

L. H. Ervin, USA

Shock Initiation and the Critical Energy Concept, P. M. Howe, R. B. Frey, and V. M. Boyle.

USA

Shock Initiation of High Density PETN, J. Wackerle, J. O. Johnson, and P. M. Halleck, USA

On Shock Wave Explosive Decomposition, A. N. Dremin and K. K. Shvedov, USSR

Investigation of Some Cast TNT Properties at Low Temperature, V. M. Titov,

V. V. Silvestrov, V. V, Kravtsov, and I. A. Stadnitshenko, USSR

Modes of Shock Wave Growth in the Initiation of Explosives, J.

and D. R. Hardestv, USA

Geometrical Shock Focusing and Flying Plate Initiation of Solid

A. C. sChWarZ, USA‘,

W. Nunziato, J. E. Kennedy,

Explosives, J, Q. Searc> rmd

Critical Conditions for Shock Initiation of Detonation in Real Systems, R. H. F. Stresau and

J. E. Kennedy, USA

A P“ t Detonation Criterion from Thermal Explosion Theosy, D. B. Hayes, USA

Initiation of Several Condensed Explosives by a Given Duration Shock Wave,

Y. de Longueville, C. Fauquignon, and H. Moulard, France

Initiation of Detonation in Insensitive Liquid Explosives by Low-Amplitude Compression

Waves, J. E. Hay and R. W. Watson, USA

Cellular Structure of Detonation in Nitromethane Containing Aluminum Particles, Y. Kato

and C. Brochet, France



.

r

6.0133

6.0143

6.0151

6.0162

6.0173

6.0183

6.0195

6.0204

6.0214

6.0225

6.0231

6.0250

6.0258

6.0267

6,0272

6,0281

6.0290

6.0299

6.0305

6.0312

6.0325

Effects of Liquid Diluents on Detonation Propagation in Nitromethane, M. Kusakabe and

S. Fujivmra, Japan

Shock-Induced Electrical Polarization of Homogeneous Explosives, A. N. Drcmin,

A. G. Antipenko, and V. V. Yakushev, USSR

Some Applications of the Electrical Junction Effect in Experimental Shock Studies,

J. P. Remain and J. Jacquesson, France

The JCZ Equations of State for Detonation Products and Their Incorporation in the TIGER

Code, M. Cowperthwaite and W. H. Zwisler, USA

Sympathetic Detonation of Ammonium Perchlorate by Small Amounts of Nitroguanidine,

A. J. Tulis, USA

Further Studies on the Detonation Characteristics of Very Low Density Explosive Systems,

A. J. Tulis and J. L. Austing, USA

Deflagration Rate of Composite High Explosive and Composite Propellants at Pressures

Above 1 Kilobar, P. Benhaim and J. Goliger, France

Effects of Confinement and Initial Pressure on the Deflagration of Some High Explosives,

O. Listh, Sweden

The Thermal Decomposition and Reaction of Confined Explosive, E. Catalano,

D. L. Omellas, E. Wrenn, E. L. Lee, J. Walton, and R. R. Mcguire, USA

Retarded Detonation, M. Held, D. Ludwig, and P. Nikowitsch, West Germany (FRG)

Deflagration to Detonation Transition Studies for Two Potential Isometric Cast Prima~

Explosives, C. M. Tarver, T. C. Goodale, R. Shaw, and M. Cowperthwaite, USA

On the Mechanism of Deflagration to Detonation Transition in Gas-Permeable High

Explosive, A. A. Sulimov, B. S. Emlolaev, A. A. Bonsov, A. I. Korotkov, B. A. Khasainov,

and V. E. Khrapovsky, USSR

A Comparison of Model Predictions and Experimental Results of DDT Tests, D. T. Pilcher,

L. W. Christensen, M. W. Becksted, and A. J. King, USA

Shocks Retardation and Presence of Cracks in Materials, B. M. Belgaumkar, India

Sensitivity of Explosive Substances, a Multivariate Approach, S. Ek, Sweden

Instability of Heterogeneous Deflagration Waves, L. de.~uca, Italy

The Growth of Reaction in Secondaxy Explosives under Transient Confinement,

G. D. Coley, UK

Propellant Detonation Risk Testing, H. J. Pasman, E. E. A. Cruysberg, and

T. M. Groothuizen, Netherlands

Volume and Pressure Dependence of Some Kinetic Processes in Explosives, D. J. Pilstine,

M. J. Kamlet, and S. J. Jacobs, USA

The Relationship of Impact Sensitivity with Structure of Organic High Explosives:

I. Polynitroaliphatic Explosives, M. J. Kamlet, USA

Initiation of Violent Reaction by Projectile Impact, R. B. Frey, G. Melani, M. Chawla, and

J. Trimble, USA

.

.

.

14



6.0336

6.0344

6.0352

6.0371

6.0379

6.0389

6.0390

6.0396

6.0405

. 6.04140

. 6.0426

6,0439

6.0450

6.0455

6,0460

6.0466

6.0477

6.0489

6.0502

6.0510

.

.

A Numerical Study of hnpact Phenomena in Explosives and Propellants, C. A. Kot,

A. H. Wiedermann, H. S. Napadensky, and Y. A. Shikari, USA

A Kinetic Lattice Approach to Detonation in Heterogeneous Explosives, R. F. Chaiken and

J. C. Edwards, USA

Perturbation Methods Applied to Problems in Detonation Physics, J. B. Bdzil, USA

A Simple Model for the Simulation of the Initiation of Detonation by a Shock Wave in

Heterogeneous Explosive, A. A. Schilperoord, Netherlands

Chemical Kinetic and Curvature Effects on Shock Wave Evolution in Explosives, P. J. Chen

and J. E. Kennedy, USA

The Hugoniot and Shock Initiation Threshold of Lead Azide (Abstract Only), F. W. Davies,

A. B. Zimmerscheid, F. G. Borgardt, and L. Avrami, USA

Electric Field Initiation of Explosive Azides, T. Gora, D. S. Downs, H. D. Fair, and P. Mark,

USA

Adiabatic Elastic Moduli of Single Crystal Pentaerythritol Tetranitrate (PETN), C. E. Morris.

USA

Two Dimensional Homogeneous and Heterogeneous Detonation Wave Propagation,

C. L. Mader, USA

High Resolution Photography of Transverse Wave Effects in the Detonation of Condensed

Explosives, P. -A. Persson and G. Persson, Sweden

Deflagration to Detonation Transition Behavior of Tetryl, R. R. Bemecker, D. Price,

J. O. Erkman, and A. R. Clairmont, USA

Improvement of Performance of Composite Explosives Containing Ammonium Nitrate by

Physical Synthesis, J. Hershkowitz and 1. B. Akst, USA

Homogeneous Liquid Explosives Containing Ureaperchlorate, S. Fujiwam, M. Kusakabe, and

K. Shiino, Japan

A New Explosive for Low Voltage Detonator Applications, W, B. Leslie, R. W. Dietzel,

J. Q. Searcy, USA

BTX - A Useful High Temperature EBW Detonator Explosive, R. H. Dinegar, L. A.

Carlson, and M. D. Cobum, USA

Physical, Stability, and Sensitivity Properties of Liquid “~xplosives, K. Scribner, R. E. Elson,

R. R. Fyfe, and J. P. Cramer, USA

Dynamic Detection of the Onset of Spalling in Stainless Steel on Comp. B, C. P. M. Smith.

G. Eden, and B. D. Lamboum, UK

The Critical Angle for Mach Bridge Fomlation Between Opposing Shock Waves in

Polyurethane Foam, R. M. James, P. W. J. Moore, and B. D. Lamboum, UK

On Blast Waves in Liquids, M. M. Kamal, G. E. Abouseif, R. H. Guiguis, S. A. Farag, and

A. K. Oppenheim, Egypt

Effects of Aluminum and Lithium Fluoride Admixtures on Metal Acceleration Ability of

Comp B, G. Bjarnholt, Sweden

15

I



6.0521

6.0528

6.0540

6.0551

6.0561

6.0570

6.0590

6.0602

6.0612

6.0625

‘ 6.0637

6.0642

6.0653

6.0664

6.0668

6.0673

6.0682

6.0691

6.0700

6.0710

6.0723

16

Acceleration of Spherical Metal Shells by High Explosives: Detonation Velocity Along the

Shell Surface and Efficiency of Energy Transfer, H. V. Freund, W. Geiger, and G. Honcia,

West Germany (FRG)

Calculated Spherical Shock Waves Produced by Condensed Explosives in Air and Water,

H. M. Steinberg and H. Hunvitz, USA

Explosive Expansion Works in Undenvater Detonations, G. Bjamholt and R. Hohnberg,

Sweden

Optimisation of Explosives for Use Underwater, A. N. Hicks, UK

The Effect of Explosive Properties on the Shock Wave Parameters of Undenvater Explosions,

B. D. Lamboum, UK

The Unsteady Regular and Mach Reflection Resulting from the Interaction of Spherical

Explosion Shock Waves in Water, J. W, Enig, USA

The Problem of Strong Point Explosion in a Combustible Medium, S. Eidehnan,

Y. M. Timnat, and A. Burcat, Israel

Perpendicular Explosive Drive and Oblique Shocks, T. R. NeaI, USA

Laser Initiation of Insensitive High Explosives, L. C. Yang and V. J. Menichelli, USA

Detemlination of Detonation Pressure Using a Manganin Wire Technique, K. Burrows,

D. K. Chilvers, R. Gyton, B. D. Lamboum, and A. A. Wallace, UK

Magnetic Probe Measurements of Particle Velocity Profiles, W. C. Davis, USA

The Diameter Effect in High-Density Heterogeneous Explosives, R. Engelke and

A. W. Campbell, USA

Acceleration of Thin Flyers by Exploding Metal Foils: Application to Initiation Studies,

R. C. Weingart, R. S. Lee, R. K. Jackson, and N. L. Parker, USA

Multiple-Exposure Image Intensifier Camera, O. G. Winslow, W. C. Davis, and W. C. Chiles,

USA

The Use of a Dual-Delay-Leg Velocity Interferometer with Automatic Data Reduction in a

High-ExpIosive Facility, R. A. Lederer, S. A. Sheffield, A. C. Schwarz, and D. B. Hayes,

USA

Wide Range Velocity Interferometer, B. T. Amery, UK

Assessment Methods of the Impact Ignition Sensitivity o’~Difflcultly-Detonable Explosives.

W. H. Andersen and N. A. Louie, USA

Shaped Charge Temperature Measurement, W. G. Von Holle and J. Trimble, USA

The Hydrostatic Compression of Explosives and Detonation Products to 10 GPa (100 kbars)

and Their Calculated Shock Compression: Results for PETN, TATB, COZ and 1-120,

B. Olinger and H. H. Cady, USA

The Effect of Elemental Composition on the Detonation Behavior of Explosives, M. Finger.

E. L. Lee, F. H. Helm, B. Hayes, H. C. Homig, R. R. Mcguire, M. Kahara, and M. Guid~,

USA

Detonation Characteristics of Liquid Nitric Oxide, W. C. Chiles and J. B. Ramsay, USA

.

I..

. I

.



6.0729

6.0740

6,0748

6.0755

6.0766

6.0777

6.0786

7.0003

7.0017

. 7.0024.

. 7.0036

7.0043

7.0050

7.0056

7.0065

7.0073

7.0084

7.0093

7.0107

7.0119

7.0139

Characterization of Commercial, Composite Explosives, M. Finger, F. H. Helm, E. L. Lee,

H. Cheung, B. Hayes, L. Penn, J. Walton, and R. Boat, USA

The Equation of State and Shock Initiation of HNS H, F. W. Davies, J. Shrader,

A. B. Zimmerscheid, and J, F. Riley, USA

The Equation of State and Chemical Kinetics for Hexanitrostilbene (HNS) Explosive,

S. A. Sheffield, D. E. Mitchell, and D. B. Hayes, USA

Initiation and Detonation Characteristics of TATB, R. K. Jackson, L. G. Green, R. H. Barlett,

W. W. Hofer, P. E. Kramer, R. S. Lee, E. J. Nidick, L. L. Shaw, and R. C. Weinga-t, USA

Computed and Experimental Hugoniots for Unreacted Porous High Explosives, J. O. Erkman

and D. J. Edwards, USA

The Influence of Inert Cases on Airblast: An Experimental Study, W. S. Filler, USA

A Multiple Lagrange Gage Study of the Shock Initiation Process in Cast TNT,

M. Cowperthwaite and J. T. Rosenberg, USA

Ignition of Solid High Explosive by the Rapid Compression of an Adjacent Gas Layer,

J. Starkenberg, USA

The Influence of the Dynamic Compressive Strength Properties of HE Formulations on the

Growth of Reaction, G. D. Coley and C. E. Whatmore, UK

Effect of Polymers on the Drop-Weight Sensitiveness of Explosives, G. M. Swallowe and

J. E. Field, UK

The Initiation of Explosive Charges by Rapid Shear, R. B. Frey, USA

Thermal Explosion Hazard of Thin Layers of Gelatine Dynamite, A. Persson and L. Jerberyd,

Sweden

Electron Beam Initiation of High Explosives, A. Stolovy, J. B. Aviles, E. C. Jones, and

A. L Namenson, USA

Chemical Decomposition Models for the Thermal Explosion of Confined HMX, TATB, RDX,

and TNT Explosives, R, R. Mcguire and C. M. Tarver, USA

Molecular Electronic Structure and Initiation of Secondary Explosives, A. Delpuech,

J. Cherville, and C. Michaud, France

Thernlal Decomposition of RDX Below the Melting Po!nt, H. L. Pugh, L. P. Davis,

J. S. Wilkes, W. R. Carper, and R. C. Dorey, USA

Some Comments Regarding the Sensitivities, Thermal Stabilities, and Explosive Perform ante

Characteristics of Fluorodinitromethyl Compounds, M. J. Kamlet and H. G. Adolph, USA

The Role of Excited Electronic States in the Bond-Scission Process in Detonation Reactions,

R. D. Bardo, USA

Studies on Transition from Deflagration to Detonation in High Explosives at Vexy Small

Diameters, R. Thivet and L. R. Guy, France

Deflagration-to-Detonation Transition Studies of Porous Explosive Charges in Plastic Tubes.

R. R. Bemecker, H. W. Sandusky, and A. R. Clainnont, USA

Deflagration Detonation Transition in Waxed RDX, M. Samirant, France

17



7.0143

7.0151

7.0164

7.0175

7.0186

7.0198

7.0216

7.0225

7.0234

7.0247

7.0256

7.0265

7.0273

7.0278

7.0285

7.0299

7.0308

7.0316

7.0325

7,0336

Effects of Igniter and Compaction on DDT Run Up in Plastic Pipes, A. G. Butcher,

R. L. Keefe, N. J. Robinson, and M. W. Becksted, USA

Experimental Study of Deflagration to Detonation Transition Case of Ammonium Perchlorate,

C. Maurin, J. C. Derrien, P. Deneuville, and P. Monteagudo, France

Transitions from Laminar Burning for Porous Crystalline Explosives, R. A. Fifer and

J. E. Cole, USA

Defbgration from an Ignition Site of a Confined Explosive Charge as a Function of Venting

by Orifice Flow, J. Hershkowitz, L. M. Chang, and H. E. Hudgins, USA

Improved Prediction of Flame Spreading During Convective Burning in Solid Propellant

Cracks, S. M. Kovacic, M. Kumar, and K. K. Kuo, USA

A Mechanism for the Burning Rate of High Density, Porous Energetic Materials,

D. E. Kooker and R. D. Anderson, USA

Role of Gas Phase Reactions in Deflagration-to-Detonation Transition, T. L. Boggs,

C. F. Price, A. I. Atwood, D. E. Zum, and R. L. Derr, USA

Phenomenology of the Deflagration to Detonation Transition in Propellants and Explosives,

M. Cowperthwaite, USA

Burning and Detonation, C. A. Forest, USA

Nondetonative Explosions in Confined Explosive Charges, R. B. Frey and J. Trimble, USA

Delayed Detonation in Propellants from Low Velocity Impact, L. G. Green, E. James,

E. L. Lee, E. S. Chambers, C. M. Tarver, C. Westmoreland, A. M. Weston, and B. Brown,

USA

Delayed Detonation in Card Gap Tests, R. L. Keefe, USA

Shock Initiation of Explosives by the Impact of Small Diameter Cylindrical Projectiles,

L. G. Green, USA

Shock Initiation in Gap Test Configurations, G. C. W. Foan and G. D. Coley, UK

Shock Initiation and Subsequent Growth of Reaction in Explosives and Propellants: The

Low-Amplitude Shock Initiation Test, LASI, D. G. Tasker, UK

An [instrumented Shotgun Facility to Study Impact-Initiated Explosive Reactions,

R. C. Jensen, E. J. Blornmer, and B. Brown, USA

Initiation of Burning and Detonation in Cast H-6 and Ca& PBXW-109, T. P. Liddiard and

J. W. Forbes, USA

Critical Conditions for Shock Initiation of Detonation by Small Projectile Impact,

H. Moulard, France

The Shock Initiation of Bare and Covered Explosives by Projectile Impact, K. L. Bahl,

H. C. Vantine, and R. C. Weingart, USA

The Sensitivity to Initiation of HE-Wax Compounds at Different Temperatures, Ch. Klee and

D. Ludwig, West Germany (FRG)

.

.

.Is

I



7.0343

7.0352

7.0362

7,0373

7.0385

7.0394

7.0408

7.0416

7.0423. .

7.0435.

7.0448

7.0459

7.0466

7.0479

7.0488

7.0498

7.0506

7.0517

7.0523

7.0531

Formation and Distribution of Hot Spots in Shy Explosives Under Projectile Impact,

K. K. Feng, W. K. Chung, J. M. Yu, and B. C. -Y. Lu, Canada

The Mechanism of Initiation of Composition B by a Metal Jet, M. C. Chick and D. J. Hatt,

Australia

Investigation of Transient Processes at Initiation of High Explosives, V. M. Titov,

V. F. Lobanov, S. A. Bordzilovsky, and S. M. Karakhanov, USSR

Effect of Cavitation on the Shock Sensitivity of Liquid Explosives, V. K. Mohan and

J. E. Hay, India and USA

Shock Initiation of Porous TATB, A. B. Anderson, M. J. Ginsberg, W. L. Seitz, and

J. Wackerle, USA

Hot Spot Initiation of Heterogeneous Explosives, M. E. Kipp, J. W. Nunziato, R. E. Setchell.

and E. K. Walsh, USA

Diverging Detonations in RDX- and PETN-Based Cast-Cured PBX, F. Bonthoux,

P. Deneuville, and Y. de Longueville, France

Shock Characterization of Hexanitroazobenzene (l-INAB), L. M. Lee and A. C. Schwarz,

USA

Shock Initiation of TATB Fomlulations, C. Honodel, J. Hunlphrey, R. C. Weingart,

R. S. Lee, and P. E. Kramer, USA

Two-Phase Visco-P1astic Model of Shock Initiation of Detonation in High-Density Pressed

Explosives, B. A. Khasainov, A. A. Borisov, B. S. Emlolaev, and A. 1. Korotkov, USSR

The Initiation Transient in Dilute Explosives, W. Fickett, USA

Model of Impact Ignition and Explanation of Critical Shock Initiation Energy:

II. Application, W. H. Andersen, USA

The Accuracy of Reaction Rates Inferred from Lagrange Analysis and In-Situ Gauge

Measurements, H. C. Vantine, R. B. Rainsberger, W. D. Curtis, R. S. Lee, M. Cowperthwaite,

and J. T. Rosenberg, USA

Numerical Modeling of Shock Sensitivity Experiments, A. L. Bowman, C. A. Forest,

J. D. Kershner, C. L. Mader, and G. H. Pimbley, USA

Modeling Two-Dimensional Shock Initiation and Detonation Wave Phenomena in PBX 9404

and LX-1 7, C. M. Tarver and J. O. Hallquist, USA . ‘

A Constitutive Model for Calculating Chemical Energy Release Rates from the Flow Fields

in Shocked Explosives, M. Cowperthwaite, USA

A Void Collapse Model for Shock Initiation, Y. Partom, Israel

Modeling Studies of the Performance Characteristics of Composite Explosives,

C. Westnloreland and E. L. Lee, USA

Hot Spot and Bulk Temperature Induction in Shock Compressed Explosives, M. J. Frankel

and D. J. Pastine, USA

Detonation Pressures of PBX-9404, Conlposition B, PBX-9502, and Nitromethane,

W. C. Davis and J. B. Ramsay, USA

!9



7.0540

7.0548

7.0560

7.0566

7.0575

7.0583

7.0589

7.0602

7.0608

7.0620

.7.0624

7.0634

7.0641

7.0646

7.0661

7.0669

7.0678

7.0686

7.0695

7.0703

7.0716

Comparison of TATB and DINGU Explosive Properties, P. Deneuville, C. Gaudin,

Y. de Longueville, and J. Mala, France

Detonation in Intermolecular Explosives: Characteristics of Some Eutectic Formulations, I.

B. Akst, USA

Influence of Inert Binders on Detonation Properties of Cast-Cured PBX, Y. de Longue~ille.

A. Delclos, C. Gaudin, and J. Mala, France

Customized Explosives based on Plastic-Bonded Mixtures to TATB and HMX,

A. W. Campbell, H. L. Flaugh, A. Popolato, and J. B. Ramsay, USA

On the Low-Velocity Detonation of Nitrometha.ne, A. A. Schilperoord, Netherlands

Influence of Additives on Nitromethane Detonation Characteristics, H. N. Presles, C. Brochet,

Y. Kate, and K. Tanaka, France and Japan

A Theory to Predict the Velocity-Diameter Relation of Explosives, S. K. Chan, UK

Some Results on the Converging Spherical Detonation in a Solid Explosive, R. Cheret, F.

Chaisse, and J. Zoe, France

Numerical Simulation of Detonation Failure in Nitromethane, M. E. Kipp and J. W. Nunziato.

USA

Nonideal Detonation and Initiation Behavior of a Composite Solid Rocket Propellant,

J. J. Dick, USA

Comer-Turning in TATB, M. Cox and A. W. Campbell, USA

The Chapman-Jouguet Detonation and its Acceleration for a Perfect Fluid Without

Conduction, G. Damamme, France

Simulation of the Reaction Zone of Heterogeneous Explosives, G. Drunamme and

M. Missonier, France

Postdetonation Behavior of Condensed High Explosives by Modem Methods of Statistical

Mechanics, F. H. Ree, USA

Influence of the Reaction Zone on the State of Detonation in a Steady Axial Wave,

J. Thouvenin, France

Detonation Wave Interactions, C. L. Mader, USA

Explosive Equation of State Determination by the AWRE Method, W. A. Bailey,

R. A. Belcher, D. K. Chilvers, and G. Eden, UK‘.

An Elementary Solution for the Equations of the Zeroth Order Internal Structure of a Strong

Detonation in a Solid High Explosive, F. Chaisse, R. Cheret, S. Paul, and J. M. Semas,

France

Numerical Simulations of Non Ideal Detonations of a Heterogeneous Explosive with the

Two-Dimensional Eulerian Code C. E.E., P. Donguy and N. Legrand, France

Detonation Properties of Condensed Explosives Calculated with an Equation of State Based

on Intemlolecular Potentials, R. Chirat and G. Pittion-Rossillon, France

Theoretical EOS for Reaction Products of RDX, H. D. Jones, USA



7.0721

7.0735

7.0746

7.0751

7.0759

7.0768

7.0777

7.0789

7.0795. 7.0801

7.0811

.7.0826

7.0834

7.0843

7.0857

7.0865

7.0877

7.0887

7.0898

7.0906

7.0914

7.0924

Development of a Single Species Equation of State for Detonation Products Suitable for

Hydrocode Calculations, L. H. Sentman, R. A. Strehlow, B. Haeffele, and A. Eckstein, USA

Low Energy Laser Initiation of Single Crystals of Beta-Lead Azide, J. T. Hagan and

M. M. Chaudhri, UK

Mesll-Initiated Large-Area Detonator with Magnetic Flux Compression Current Generator as

Source, Sang Wu, Zhang Guan-Ren, China (PRC)

Inverse Multi-Streak Technique, M. Held and P. Nikowitsch, West Germany (FRG)

Detonation Temperature of Some Liquid Explosives, J. T. A. Burton, S. J. Hawkins, and

G. Hooper, UK

Brightness Temperature of Detonation Wave in Nitronlethane-Tetranitro-Methane Mixtures

and in Gaseous Mixtures at a High Initial Pressure, Y. Kate, P. Bauer, C. Brochet, and

R. Bouriannes, Japan and France

Comparison of Molecular Dynamics Calculations with Observed Initiation Phenomena,

F. E. Walker, A. M. Karo, and J. R. Hardy, USA

On Decomposition Reaction Kinetics in Shock Wave Front, A. N. 13remin, V. Y. Klimenko,

K. M. Michailjuk, and V. S. Trofimov, USSR

A Short Suwey of Detonation Research in China, Ding Jing, China (PRC)

Eutectic Composite Explosives Containing Ammonium Nitrate, M. M. Stinecipher, USA

The Acceleration of Two Metal Plates in an HE-Metal Sandwich, N. E. Hoskin and

B. D. Lamboum, UK

The Planar Flyer Plate Driven by Detonation Product Convergent Flow, Tan Bing-Sheng and

Jing Fu-Qian, China (PRC)

An Improved Approximate Model of Explosive Casing Expansion, M. Komhauser, USA

Compaction of Porous Beds of Inert Materials, H. W. Sandusky, W. L. Elban, K. Kim,

R. R. Bemecker, S. B. Gross, and A. R. Clairmont, USA

Sl~ort-Pulse Shock Initiation of Granular Explosives, R. E. Setchell, USA

Characterization of the DDT Explosive, CP, P. L. Stanton, E. A. Igel, L. M. Lee,

J. H. Molder, and G. T. West, USA

Precursors in Detonations in Porous Explosives, R. L. Spaulding, USA

Correlation of the Results of !Wock Initiation Tests, A. “M. Weston, J. Kincaid, E. James,

E. L. Lee, L. G. Green, and J. Walton, USA

Anomalous Burning Rate Characteristics of Composition B and TNT, R. W. Velicky and

J. Hershkowitz, USA

Shock Ignition Sensitivity of Multiply-Shocked Pressed TNT, V. M. Boyle and D. L. Pilarski,

USA

The Effect of Base Gaps on Setback-Shock Sensitivities of Cast Composition B and TNT as

Determined by the NSWC Setback-Shock Simulator, T. F. Myers and J. Hershkowitz, USA

Exploding Foil Shock Sensitivity Test, W. E. Voreck and R. W. Velicky, USA

.

? 21



7.0930

7.0940

7.0952

7.0958

7.0965

7.0970

7.0976

7.0986

7.0993

7.1004

7.1010

7.1016

7.1024

7.1029

7.1040

7.1048

7.1055

7.

7.

062

072

8.0003

The Role of Air and Other Gases in Flyer Plate Initiation of Explosives, J. G. Harlan,

J. K. Rice, and J. W. Rogers, USA

Detonation Chemistry: An Investigation of Fluorine as an Oxidizing Moiety in Explosives,

R. R. McGuire, D. L. Omellas, F. H. Helm, C. L. Coon, and M. Finger, USA

Simplified Methods for Predicting Explosive Performance Parameters Including Eremenko’s

Relative Detonation Impulses, J. M. Short, H. G. Adolph, and M. J. Kamlet, USA

Fine Structure in Nitromethane/Acetone Detonation, W. C. Davis, USA

Laborato~-Scale Sensitivity Testing of Insensitive High Explosives, J. M. Brosse, C. Kassel,

C. Michaud, and S. Poulard, France

Experimental Investigation of Hot Spots Produced by High Rate Defomlation and Shocks,

C. S. Coffey, M. J. Frankel, T. P. Liddiard, and S. J. Jacobs, USA

Microhardness Study of RDX to Assess Localized Deformation and its Role in Hot Spot

Fomlation, W. L. E1ban and R. W. Amlstrong, USA

Flash X-Ray Cineradiography @ 100,000 fps, J. J. Trimble and C. L. Aseltine, USA

Temperature Measurement of Shocked Explosives by Time-Resolved Infrared Radiometry-

A New Technique to Measure Shock-Induced Reaction, W. G. Von Hone and C. M. Tamer,

USA

Thermocouple Temperature Measurements in Shock-Initiated PBX-9404, D. D. Bloomquist

and S. A. Sheffield, USA

Raman Scattering Temperature Measurement Behind a Shock Wave, F. Boisard, C. Tombini,

and A. Menil, France

Aquarium Tests on Aluminized ANFO, S. Goldstein and J. N. Johnson, USA

Shock Initiation Sensitivity of Hexanitrostilbene (I-INS), A. C. Schwarz, USA

Interpolation of Detonation Parameters from Experimental Particle Velocity Records,

B. Hayes and C. M. Tamer, USA

Factors Affecting the Explosiveness of Munitions Fillings, A. S. Dyer, P. J. Hubbard,

P. R. Lee, and D. G. Tisley, UK

The Response of Confined Explosive Charges to Fragment Attack, P. M. Howe, J. L. Watson,

and R. B. Frey, USA

A Numerical Study of Detonation Propagation Between I(4unitions, P. M. Howe,

Y. K. Huang, and A. L. Arbuckle, USA

The Electromagnetic Velocity Gauge: Use of Multiple Gauges, Time Response, and Flow

Perturbations, L. M. Erickson, C. B. Johnson, N. L. Parker, H. C. Vantine, R. C. Weingart,

and R. S. Lee, USA

Lagrange Gage Studies in Ideal and Non-Ideal Explosives, M. Cowperthwaite and

J. T. Rosenberg, USA

The Relationship Behveen the Shock Sensitivity and the Solid Pore Sizes of TATB Powders

Pressed to Various Densities, R. S. Lee, G. Bloom, W. G. Von Hone, R. C. Weingart,

L. M. Erickson, S. Sanders, C. Slettevold, and R. R. McGuire, USA .

.

I



8.0015

8.0026

8.0035

8.0042

8.0052

8.0062

8.0068

8.0083

8.0089

8.0093

. .8.0099

.

8.0111

8.0123

8.0135

8.0143

8.0151

8.0159

8.0168

8.0176

Experimental Studies of Chemical Reactivity during Shock Initiation of Hexanitrostilbene,

R. E. SetcheIl, USA

The Effects of Material Microstructure on the Shock Sensitivity of Porous Granular

Explosives, P. A. Taylor, USA

Modeling Granular Explosive Detonations with Shear Band Concepts, M. E. Kipp, USA

The Three-Dimensional Hydrodynamic Hot-Spot Model, C. L. Mqder and J. D. Kershner,

USA

Modeling Heterogeneous High Explosive Bum with an Explicit Hot-Spot Process,

P. K. Tang, J. N. Johnson, and C. A. Forest, USA

Hot Spot Production by Moving Dislocations in a Rapidly Deforming C~staHine Explosive,

C. S. Coffey, USA

Cavity Collapse in Energetic Materials, R. B. Frey, USA

Hugoniots and Reaction Rates from EMV Gauge Measurements and Lagrange Analysis,

Jiao Qinjie, Ding Jing, Liang Yunming, Huang Zhengping, and Zhao henyang, China (PRC)

Measurement of Two-Dinlensional Shock Wave Velocities and a Composite Probe,

Fu Xinghai, China (PRC)

Resonation Phenomenon in Solid Explosives, Ding Jing, Bi Zhu, Hu Dong, and

Deng Quan-nong, China (PRC)

Reaction Rates from Electromagnetic Gauge Data, J. Vorthman, G. Andrews, and

J. Wackerle, USA

Lagrange Gage Studies of Detonation in Some Intermolecular EA-Based Explosives,

M. Cowperthwaite and J. T Rosenberg, USA

Detonation Reaction Zone Studies on TATB Explosives, W. L. Seitz, H, L. Stacy, and

J. Wackerle, USA

Experiments and Numerical Simulation of High Explosive Delayed and Lowed Detonation,

J. Vanpoperynghe, J. Sorel, and H. C. Pujols, France

Pressure Variation upon Initiation of Cast RDX/TNT 50/50 Charge by Diverging Shock

Wave, V. M. Titov, S. M. Karakhanov, and S. A. Bordzilovsky, USSR

Experimental Study of Spherically Diverging Detonation Waves, J. Aveille, J. Baconin,

N. Carion, and J. Zoe, France .

A Theoretical Analysis of the Shape of a Steady Axisymmetrical Reactive Shock Front in

Cylindrical Charges of High Explosive, a Curvatnre-Diarneter Relationship, F. Chaisse,

J. M. Servas, J. Aveille, J. Baconin, N. Carion, and P. Bongrain, France

A Generalized C-J Condition for Simple Axial Flow with a Spherical Shock Front: Its

Application to the Slurry Explosives, H. Matsui, A. Moritani, K. Yoneda, and T. Asaba,

Japan

A Small Divergent Detonation Theory for Intermolecular Explosives, I. J. Kirby and

G. A. Leiper, Scotland, UK

.

●


Sy,Pg Title, Authors, Country

8.0187

8.0196

8.0207

8.0211

8.0228

8.0243

8.0251

8.0262

8.0274

8,0284

8.0294

8.0307

8.0318

8.0330

8.0337

8.0351

8.0361

8.0372

8.0380

8.0390

8.0399

8.0409

Determination of Reaction Rates in Intermolecular Explosives Using the Electromagnetic

Particle Velocity Gauge, G. A. Leiper, I. J. Kirby, and A. Hackett, Scotland, UK

Determination of Transient and Kinetic Characteristics in Simulating RDX/TNT 50/50 Clmrgc

Initiation, V. M. Titov, V. F. Lobanov, S. A. Bordzilovsky, and S. M. Karakhanov, USSR

The Influence of Reactive Cases on Airblast from High Explosives, W. S. Filler, USA

The Growth and Decay of Explosive Deflagrations in Munitions in Simulated Factory

Accident Scenarios, A. S. Dyer, P. J. Haskins, P. J. Hubbard, and C. D. Hutchinson, UK

An Eight-Inch-Diameter, Heavily Confined Card Gap Test, J. Foster, K. Forbes, M. Gunger,

and B. G. Craig, USA

Chemical Reaction of Explosives and Gun Propellant during High Acceleration,

M. Y. D. Lanzerotti and J. Pinto, USA

The Effect of Some Additives on the Closed Bomb Burning and Ignitability of RDX/TNT,

R. W. Velicky, H. W. Voight, and W. E. Voreck, USA

Response of Confined Explosive Charges to Fragment Impact, M. A. Barker, M. J. F. Basset.

J. Conner, and P.J. Hubbard, UK

Pressure-Shear Loading of PBX-9404, L. C. Chhabildas and M. E. Kipp, USA

Energetic Response of Propellants to High-Velocity Impact, L. G. Green, E. James, and

E. L. Lee, USA

An Experimental Investigation of the Role of Shear in Initiation of Detonation by Impact,

P. M. Howe, G. Gibbons, and P. E. Webber, USA

Some New Computed Results for Projectile Impact Shock Initiation of Solid Explosives.

Y. K. Huang, J. Starkenberg, and A. L. Arbuckle, USA

The Jet Initiation of Solid Explosives, M. C. Chick, 1. B. Macintyre, and R. B. Frey,

Australia and USA

Superposition of Shock Waves and Reaction Waves for the Initiation of High Explosive

Charges, M. Held, West Germany (FRG)

Numerical Simulation of Jet Penetration of HMX and TATB Explosives, D. Pirotais,

J. P. Plotard, and J. C. Braconnier, France

Sensitivity and Perfomlance Characterization of DINGU, M. M. Stinecipher and L. A. Stretz,

USA

Shock Sensitivity Study of the Curable Plastic Bonded Explosives, C. Bekmger, J. F. Drolet.

and P. Pelletier, Canada

Effect of Confinement on Failure in 95 TATB/5 KEL-F, J. B. Ramsay, USA

Run to Detonation in TATB, D. Grief, S. H. Ward, and G. D. Coley, UK

The Use of the Double Pipe Test to Investigate the Run-Up and Run-Down from Initiation in

Pneumatically Loaded ANFO, M. P. du Plessis and C. M. Lownds, South Africa

Simulating the Initiation of High Explosive by Explosive Trains, F. Leibundgut, Switzerland

Influence of Air Gaps on Detonation Propagation in Charges Consisting of Stacked Blocks of

Cast TNT, A. Gibb, Canada

.

.

.

.

.

.



8.0422

8.0425

8.0431

8.0440

8.0447

8.0460

8.0468

8.0473

8.0485

8.0501.

8.0513

.

8.0521

8.0531

8.0540

8.0548

8.0558

8.0567

8.0577

8.0587

8.0596

8.0602

Detonation Properties of Liquid Nitric Oxide, W. C. Davis and W. C. Chiles, USA

Characterization of Strong Detonation Waves in Nitromethane, M. Sellam, C. Brochet, and

R. Cheret, France

Continuous Observation of Mach Bridge and Mach Phenomena, H. N. Presles, J. Souletis,

and J. Groux, France

Displacement Gradient Method for Measuring Detonation Parameters Using Flash X-Ray

Photography, Li Huiling, Huang Zhengping, and Ding Jing, China (PRC)

The Study of Booster Materials with Electromagnetic Particle Velocity Gauges,

D. A. Philipart, UK

Applications of Fiber Optics to Detonation Events, P. Lu, E. Naiman, and W. E. Voreck,

USA

VISAR: Interferometer Quadrature Signal Recording by Electronic Streak Camera,

W. F, Hemsing, USA

Laser as a Tool in Sensitivity Testing of Explosives, H. Ostmark, Sweden

Microwave Interferometer Techniques for Detonation Study, P. L. Stanton, E. L. Venturini,

and R. W. Dietzel, USA

Detonation Behavior of LX-14 and PBX-9404: Theoretical Aspect, F. H. Ree and

M. van Thiel, USA

Comparison of Experimental Data on Detonation Velocity and Chapman-Jouguet Pressure vs

Initial HE Density with Predictions from Ree’s ModeI Equation of State, D. J. Steinberg,

USA

Which Equation of State for Carbon in Detonation Products”?, J. Baute and R. Chirat, France

The Theoxy of Dense Molecular Fluid Equations of State with Application to Detonation

Products, M. S. Shaw and J. D. Johnson, USA

Theoretical Equations of State for the Detonation Products of Explosives, G. I. Kerley, USA

Detonation Properties of High Explosives Calculated by Revised Kihara-Hikita Equation of

State, K. Tanaka, Japan

Detonation Temperature of Nitromethane and Some Solid High Explosives, Y. Kate, N. Mori,

H. Sakai, K. Tanaka, T. Sakurai, and T. Hikita, Japan

The Measurement of Detonation Temperature of Conden3ed Explosives Jvith Two-Colour

Optical Fiber Pyrometer, He Xianchu, Han Chenbung, and Kang Shufong, China (PRC)

Detonation Products of Insensitive Cast High Explosives, F. Volk, H. BatheIt, F. Schedlbauer,

and J. Wagner, West Germany (FRG)

The Supracompression of LX-07, LX-17, PBX-9404, and RX-26-AF and the Equations of

State of the Detonation Poducts, L. G. Green, E. L. Lee, A. Mitchell, and C. M. Tarver, USA

EOS of Detonation Products Obtained from Symmetrical Deflection of Liners Investigated by

Laser Interferometry Techniques, P. Gimenez, Y. de Longueville, and C. Saint-Martin, France

Models of Explosively Driven Metal, J. T. Dehn, USA



8.0613

8.0625

8.0635

8.0645

8.0658

8.0669

8.0678

8.0691

8.0701

8.0710

8.0715

8.0725

8.0734

8.0742

8.0751

8.0762

8.0770

8.0778

8.0785

8.0796

8.0805

The Motion of Thin Metal Walls and the Equation of State of Detonation Products,

E. L. Lee, D. Breithaupt, C. Mcmillan, N. L. Parker, J. W. Kury, C. M. Tamer, W. Quirk,

and J. Walton, USA

Influence of Test Conditions on the Ballistic Classification of Explosives, J. Souletis, and

J. Mala, France

Mechanical Properties of PBX’S and their Behaviour During Drop Weight Impact, J. E. Field,

S. J. P. Palmer, P. H. Pope, R. Sundararajan, and G. M. Swallowe, UK

The Strain Rate Behavior of Coarse HMX Porous Bed Compaction, P. J. Coyne, W. L. Elban

and M. A. Chiarito, USA

Deflagration-to-Detonation Transition (DDT) Studies of a Double-Base Propellant,

R. R. Bemecker, H. W. Srmdusky, and A. R. Clainnont, USA

Modelling of DDT in Granular Explosives, H. J. Verbeek, Netherlands

On the Mechanism of the Reaction “Hot Spots” Origin at Liquid Explosives Detonation,

A. N. Dremin, V. Y. Klimenko, and I. Y. Kosireva, USSR

‘t’ime-Resolved Spectroscopic Studies of Detonating Heterogeneous Explosives, W. M. Trott

and A. M. Renlund, USA

Real Time Analysis of PETN Detonation Products, N. C. Blais and J. J. Valentini, USA

Fast Spectroscopic Analysis of Laser Initiated Decomposition Reactions in Explosives,

M. W. Leeuw, A. J . T. Rooijers, and A. C. van der Steen, Netherlands

Static High Pressure Study of Nitric Oxide Chernistxy: Proposed Mechanism for Nitric

Oxide Decomposition, B. I. Swanson, S. F. Agnew, and N. R. Greiner, USA

Sub-Ignition Reactions at Molecular Levels in Explosives Subjected to Impact and

Undenvater Shock, J. SImrma, J. C. Hoffsommer, D. J. Glover, C. S. Coffey, J. W. Forbes,

T. P. Liddiard, W. L. Elban, and F. Santiago, USA

Paramagnetic Decomposition Products from Energetic Materials, M. D. Pace, A. D. Britt,

W. B. Moniz, and D. Stec, USA

Param agnetic Resonance of Radicals in Decomposed Trinitroaromatics, F. J. Owens, USA

An Extensive Application of WCA4 Equation of State for Explosives, R. Chirat and J. Baute,

France

The Equation nf State of Detonation Products and Their- incorporation Into the QUATUOR

Code, O. Heuze, P. Bauer, H. N. Pres.les, and C. Brochet, France

Sensitivity Analysis of the Ideal Detonation State to Errors in Molecular Properties and

Intemlolecular Force Parameters, W. B. Brown, UK

Derivatives of the Chapnlan-Jouguet State, B. D. Lamboum, UK

Equation of State for Detonation Products, W. C. Davis, USA

Detonation Properties of Condensed Explosives Computed with the VLW Equation of State.

Wu Xiong, China (PRC)

Calculation of Detonation Products by Means of the CS Hard-Sphere Equation of State,

K. K. Feng, W. K. Chung, and B. C. -Y. Lu, Canada

“



8.0815

8.0827

8.0839

8.0847

8.0855

8.0864

8.0870

8.0881

8.0892

. 8.0902

. 8.0914

8.0926

8.0934

8.0943

8.0951

8.0962

8.0972

8.0979

8.0985

8.0993

8.1001

Expansion [sentropes of TATB Compositions Released to Argon, M. Pinegre, J. Aveille,

M. Leroy, J. C. Protat, R. Cheret, and N. Camarcat, France

Quantum Chemical Studies of Energetic Materials, P. J. Haskins and M. D. Cook, UK

Electron Density Distribution Analysis for Nitroguanidine, J. P. Ritchie, D. T. Cromer,

R. R. Ryan, R. F. Stewart, and H. J. Wasserman, USA

A Molecular Mechanism for the Initiation of Secondaxy Explosives. Influence of a Shock

Light-Coupling, S. Dufort and A. Delpuech, France

Calculated Reaction Pathways for Nitromethane and Their Role in the Shock Initiation

Process, R. Bardo, USA

The Dynamics of Shock-Induced Energy Flux in Molecular Bonds, A. M. Karo,

M. H. Mehlman, and J. R. Hardy, USA

Simulation of the Initiation of Detonation in an Energetic Molecular C~stal: The Overdri\en

Case, S. F. Trevino and D. H. Tsai, USA

Compressive Reaction in Porous Beds of Energetic Materials, H. W. Sandusky and

R. R. Bemecker, USA

Shock Initiation of TATB and HMX Explosive Compositions, J. Vanpoperynghe, J.

J. Aveille, and J. C. Adenis, France

Sorel.

The Effect of RDX Particle Size on the Shock Sensitivity of Cast PBX Formulations,

H. Moulard, J. W. Kury, and A. Delclos, France

Modeling 1-D Deflagration to Detonation Transition (DDT) in Porous Explosive,

A. M .Weston and E. L. Lee, USA

Modeling of Reaction Buildup Process in Shocked Porous Explosive, K. Kim and

C. H. Sohn, Korea

Modeling the Deflagration to Detonation Transition in Porous Beds of Propellant, C. F. Price

and T. L. Boggs, USA

A Semi-Analytical Approach to Shock Initiation in Heterogeneous Explosives, Y. K Huang

and A. L. Arbuclde, USA

Modeling Short Pulse Duration Shock Initiation of Solid Explosives, C. M. Tarver,

J. O. Hallquist, and L. M. Erickson, USA

A Model for Shock Initiation of Porous Propellants by Ramp-Induced Compression

Processes, H. Krier, C. A. Cudak, J. R. Stewart, and P. B. Butler, USA

DDT in RDX and Ball Powder: Behavior of the Porous Bed, M. Samirant, France

Detonation in Tungsten-Loaded HMX, S. Goldstein and C. L. Mader, USA

Calculation of the Blasting Performance of Some Commercial Explosives, A. Persson and

P. -A. Persson, Sweden

Detoriation Beh&io~”of Emulsion Explosives Containing Glass Microballoons, M. Yoshida,

M. Iida, K. Tanaka, S. Fujiwara, M. Kusakabe, and K. Shiino, Japan

Intermolecular Explosives, 1. B. Akst, USA



8.1011

8,1018

8.1025

8.1035

8.1045

8.1057

8.1069

8.1080

8.1091

8.1105

8.1119

8.1126

8.1131

8.1139

8.1150

9.0003

9.0018

9.0025

9.0039

9.0050

9.0058

28

The Detonation Reaction of Heterogeneous Composite Explosive, Guo Yuxian, Peng Guo.shu,

Song Jialiang, Xu Laibin, Wang Aiqin, and Zou Quanqing, China (PRC)

Composite Explosives for Metal Acceleration: The Effect of Detonation Temperature,

R. R. McGuire and M. Finger, USA

A Model Solution for Nonideal One-Dimensional Detonation Waves, M. Cowperthwaite,

USA

The Influence of Formulation Variables on the Growth of Reaction in Plastic Bonded

Explosives, K. A. Fleming, R. Bird, M. W. G. Burt, and C. E. Whatmore, UK

Initiation Studies on LX-17 Explosive, K. L. Bald, G. Bloom, L. M. Erickson, R. S. Lee,

C. M. Tarver, W. G. Von Hone, and R. C. Weingart, USA

The Shock Desensitization of PBX 9404 and Composition B-3, A. W. Campbell and

J. R. Travis, USA

On Detonation Driven Air Shocks in the Air Gap Between a Charge and Its Confinement,

G. Bjamholt and U. Smedberg, Sweden

Cavity Collapse Ignition of Composition B in the Launch Environment, J. Starkenberg,

D. L. Mcfadden, and O. R. Lyman, USA

Explosive Initiation by Very Snlall Conical Shaped Charge Jets, M. G. Vigil, USA

Experimental Studies Concerning the Response of Intermediate Explosives to Thernlal

Stimuli, C. D. Hutchinson, UK

Derivation of the P2t Detonation Criterion, E. H. Walker, UK

Shock Initiation of HNAB by Electrically Driven Flyer Plates, E. Hasman, M. Gvishi,

Z. Segalov, Y. Cannel, D. Ayalon, and A. Solomonovici, Israel

Shock Sensitivity and Performance of Several High Explosives, M. Kroh, K. Thoma,

W. Arnold, and U. Wollenweber, West Germany (FRG)

A Computational Investigation of the Effect of Shielding in Mitigating Shock Initiation

Stimuli Produced by Impact, J. Starkenberg, T. M. Dorsey, and K. J. Benjamin, USA

On the Role of Shock and Shear Mechanism in the Initiation of Detonation by Fragment

Impact, P. M. Howe, USA

Combined Pressure Shear Ignition of Explosives, V. Boyle, R. Frey, and O. Blake, USA

Particular Aspect of the Explosive Particle Size Effect on Shock Sensitivity of Cast

Formulations, H. Moulard, France

Particle Size Effects in the Initiation of Explosives Containing Reactive and Non-Reactive

Continuous Phases, R. L. Simpson, F. H. Helm, P. C. Crawford, and J. W. Kury, USA

In-Situ Study of the Chemically Driven Flow Fields in Initiating Homogeneous and

Heterogeneous Nitromethane Explosives, S. A. Sheffield, and R. Engelke, and R. R. Alcon.

USA

Decomposition of High Explosives in Shock and Detonation Waves, V. Fortov, G. I. Kanel,

T. N. Fortova, S. L Malyrenko,

Initiation of Explosive Cxystals

and A. V. Utkin, USSR

by Shock or Impact, C. S. Coffey, USA

.

.

.

.

A. Titles index (Continued)


9.0066

9.0077

9.0083

9.0089

9.0098

9.0112

9.0123

9.0133

9.0142

9.0153

9.0162

9.0172

9.0180

9.0190

9.0197

9.0209

9.0219

9.0228

9.0233

9.0246

Initiation Threshold of High Explosives in Small Flyer Plate Experiments, H. R. Kleinhan6,

F. Lungenstra6, and H. Zoellner, Germany

A Two-Dimensional Lagrangian Technique for Shock Initiation Diagnosis, Huan Shi and

Ding Jing, China (PRC)

Influence of RDX C~stal Shape on the Shock Sensitivity of PBXS, A. C. van der Steen,

H. J. Verbeek, and J. J. Meulenbrugge, Netherlands

A Lagrange Gauge Study of the Shock Initiation Process in an Intermolecular Explosive

EAK, M. Cowperthwaite, J. T. Rosenberg, and A. G. Taliancich, USA

Anomalous Shock Sensitivity/Density Relationship for Pressed Booster Explosives from a

Small-Scale Gap Test, R. J. Spear and V. Nanut, Australia

Shock Initiation of LX-17 as a Function of Its Initial Temperature, P. A. Urtiew,

L. M. Erickson, D. F. Aldis, and C. M. Tarver, USA

Initiation and Detonation Properties of the Insensitive High Explosive TATB/Kel-F 8009 5/5,

C. D. Hutchinson, G. C. W. Foan, H. R. Lawn, and A. G. Jones, UK

Fab~ Perot Velocimetry on Detonating LX-17 in Planar and Spherically Divergent

Geometries, K. L. Bahl, R. D. Breithaupt, C. M. Tarver, and W. G. Von Hone, USA

Reaction Rates of PBH-9D Explosive, Zhao Feng, Sun Chengwei, Sun Peiqi, and

Ouyaqng Denghuan, China (PRC)

Pulsed-Laser-Excited Ram an Spectra of Shock-Con~pressed

W. M. Trott, and A. M. Renlund, USA

Laser Ignition of Explosives: A Mass Spectroscopic Study

H. Nilsson and H. ostmark, Sweden

Triaminotrinitrobenzene,

of the Pre-Ignition Reaction

The Use of Time-Resolved Spectrometries in the Study of Initiation of Explosives at

Molecular Level, A. E. Delpuech, France

Vibrational Spectroscopic Investigations of Shock-Compressed Liquid Nitrogen and

Shock-Compressed Liquid Nitromethane, D. S. Moore and S. C. Schmidt, USA

Absorption Spectroscopy of Shocked Benzene, N. C. Holmes, G. Otani, P. McCandless,

S. F. Rice, USA

Zone.

and

Reaction Rates and the Charge Diameter Effect in Heterogeneous Explosives, G. A. Leiper‘t

and J. Cooper, UK

A Shock Initiation Model for Fine-Grained Hexanitrostilbene, M. E. Kipp and R. E. Setchell,

USA

A Theoretical Picture of Shock-to-Detonation Transition in a Homogeneous Explosive,

A. K. Kapila and J. W. Do[d, USA and France

Chemical Phenomena Associated with the Initiation of Thermal Explosions, T. B. Brill and

P. J. Brush, USA

The Lattice Density of States Concept and Its Role in Detemlining the Shock Sensitivih of

PETN and Nitromethane, R. D. Bardo, USA

Unified Formulation of the Reactivity of Condensed Explosives, R. Cheret, France



9.0250

9.0252

9.0259

9.0265

9.0280

9.0293

9.0306

9.0320

9.0329

9.0341

9.0354

9.0363

9.0379

9.0388

9.0396

9.0407

9.0417

9.0425

9.0435

9.0443

9.0452

The Choice Problem of Equation Determining the Condensed Reacting Media Characteristics

in Numerical Modeling of Shock Processes, V. S. Trofimov, USSR

Global Calibration of Constitutive Relationships in Explosive Reaction Zone, Huan Shi and

Ding Jing, China (PRC)

DDT--Determ ination of the Successive Phases of Phenomena, M. Samirant, France

Deflagration to Detonation in Granular HMX, J. M. McAfee, B. W Asay, A. W. Campbell,

and J. B. Ramsay, USA

Model Calculations and Experimental Measurements of the Response of HMX Porous Beds

to Deflagration and Shock, D. F. Aldis, E. L. Lee, R. L. Simpson, and A. M. Weston, USA

Compressive Combustion of Granular Materials Induced by Low-Velocity Impact, M. R. Baer

and J. W. Nunziato, USA

Compaction Wave Acceleration in Granular Energetic Material: Simulation with a Reactive

Shock Wave Model, D. E. Kooker, USA

Combined Experimental and Theoretical Investigations into the Deflagration-to-Detonation

Transition, H. J. Verbeek and A. C. van der Steen, Netherlands

Numerical Simulation of Deflagration-to-Detonation Transition for TS 3659 Propellants, T.

Hsieh and K. Kim, USA

Dynamic Compaction and Compressive Reaction Studies for Single and Double-Base Ball

Propellants, B. C. Glancy, H. W. Sandusky, P. J. Miller, and A. D. Krall, USA

DDT Studies of a High Energy Spherical Ball Propellant, R. R. Bemecker, USA

An Improved Model of the Deflagration-to-Detonation Transition in Porous Beds, C. F. Price,

A. I. Atwood, and T. L. Boggs, USA

Shock Behavior of Explosives about the C-J Point, P. W. Cooper, USA

Electrically Enhanced Detonation and Equations of State for Detonation Products,

M. Cowperthwaite, USA

The Measurement of Electrical Conductivity in Detonating Condensed Explosives, D. G.

Tasker and R. J. Lee, USA

Synthesis of Ultrafine Diamonds in Detonation Waves, V. M. Titov, V. F. Anischkin, and

I. Yu. Mal’kov, USSR

Carbon in Detonations, J. D. Johnson, USA.

Phase Changes in Carbon and Nitrogen Systems: Their Effects on the Detonation Propenies

of High Explosives, F. H. Ree and M. van Thiel, USA

The Detonation Parameters of New Powerful Explosive Compounds Predicted with a Revised

VLW Equation of State, Wu Xiong, Sun Jian, and Xiao Lianjie, China (PRC)

Theoretical Model of Explosive Detonation Products: Tests and Sensitivity Studies,

G. I. Kerley, USA

A New Simulation Method for the Efficient Calculation of Benchtn arks for Detonation

Products Equations of State, M. S. Shaw, USA

.

.

.

w

30



9.0461

9.0471

9.0478

9.0489

9.0498

9.0506

9.0513

9.0525

9.0537.

“ 9.0545

●

9.0554

9.0560

9.0566

9.0573

9.0585

9.0593

9.0604

9.0621

9.0626

9.0633

Calculations of Detonation Pressures for a Homologous Series of Polynitroaliphatic

Explosives Using a Fluid Perturbation Equation of State and a New Chemical Equilibrium

Computer Program, F. J. Zerilli and H. D. Jones, USA

A Detonation Pressure Measurement System Employing High Resistance Manganin Foil

Gauge, S. Y. Song and J. W. Lee, Korea

Heat of Detonation, the Cylinder Test, and Performance in Munitions, I. B. Akst, USA

Theoretical Prediction of High Explosives Efficiency: Application to NTO, F. Bugaut,

S. Bernard, and R. Chirat, France

Deteml ining JWL Equation of State Parameters Using the Gurney Equation Approximation,

P. J. Miller and K. E. Alexander, USA

Studies about the Equations of State of the Detonation Products, N. Carion, J. Aveille,

P. Andnot, F. Chaisse, G. Guri, M. T. Kerihuel, and M. Leroy, France

Sensitivities of Adiabatic and Griineisen Gammas to Errors in Molecular Properties of

Detonation Products, W. Byers Brown and M. Braithwaite, UK

Reactive Flow Measurements and Calculations of ZrHz-Based Composite Explosives,

M. J. Murphy, R. L. Simpson, R. D. Breithaupt, and C. M. Ta.rver, USA

Detonation Characteristics of Gun Propellants, B. W Asay, A. W. Campbell, M. J. Ginsberg,

and J. B. Ramsay, USA

Detonation Properties of Mixtures of HMX and Emulsion Explosives, J. D. Renick,

P. A. Persson, and J. A. Sanchez, USA

The Prospects for Composite Explosive, Guo Yuxian, China (PRC)

Detonation Velocity and Pressure of the Non-Ideal Explosive Ammonium Nitrate, A. Miyake,

A. C. van der Steen, and H. H. Kodde, Japan and The Netherlands

Shock Sensitivities of Energetically Substituted Benzofuroxans, M. L. Chan, C. D. Lind, and

P. Ploitzer, USA

Detonation and Shock Initiation Properties of Emulsion Explosives, J. Lee, F. W. Sandstrom,

B. G. Craig, and P. A. Persson, USA

Effect of Pressure of Shock Sensitivity of Emulsion Explosives, G. Om Reddy and

F. P. Beitel Jr., India and USA

Development of a Model of Reaction Rates in Shocked M’ulticomponent Explosives, K. Kim.

USA

A Model for the Initiation of Heterogeneous High Explosives Subject to General Compressive

Loading, J. Starkenberg, USA

Calculation of Detonation Properties of Emulsion Explosives, K. Tanaka, M. Iida,

Y. Nakayama, N. Ishiokawa, M. Yoshida, and S. Fujiwara, Japan

Chemistv of Undemvater Explosive Detonations, D. Carlson, R. Doherty, V. Ringbloom,

J. S. Deiterj and G. B. Wilmot, USA

Estimation of Performance of Underwater Explosives, D. A. Cichra and R. M. Doherty, USA

31



.

.

9.0640

9.0641

9.0657

9.0670

9.0683

9.0693

9.0701

9.0713

, 9.0724

9.0730

9.0743

9.0751

9,0757

9.0766

9.0773

9.0784

9.0798

9.0806

9.0816

32

Underwater Explosion of Emulsion Explosives, K. Hattori, Y. Kate, K. Tokita, Y. Fukatsu,

N. Mori, and A. Torii, Japan

The Fundamentals of Metal Combustion in Composite Explosives Revealed by High Speed

Microphotography, W. C Tao, A. M. Frank, R. E. Clements, and J. E. Shepherd, USA

Detonation Reaction-Zone Structure for PBX 9502, W. L. Seitz, H. L, Stacy, R. Engelke, P.

K. Tang, and J. Wackerle, USA

Reaction Zone Structure in Supracompressed Detonating Explosives, L. G. Green,

C. M, Tarver, and D. J. Erskine, USA

Lagrangian Analysis of MIV Gauge Experiments on PBX 9502 Using the Mass-Displacement

Moment Function, C. A. Forest, J. Wackerle, J. J. Dick, S. A. Sheffield, and D. R. Pettit,

USA

The Heterogeneous Explosive Reaction Zone, C. L. Mader and J. D. Kershner, USA

Using Small Scale Tests to Estimate the Failure Diameter of a Propellant, C. M. Tarver and

L. G. Green, USA

Molecular Dynamics Simulation of the Effect of Molecular Dissociation and Energy

Absorption on Detonation Structure in Energetic Solids, S. G. Lambrakos, M. Peyrard,

E. S. Oran, USA

Multiprocess Detonation Model, A. N. Dremin, V. Yu. Klimenko, O. N. Davidova, and

T. A. Zoludeva, USSR

Detonation Shock Dynamics: A New Approach to Modeling Multi-Dimensional Detonation

Waves, J. B. Bdzil, W. Fickett, and D. S. Stewart, USA

Nonequilibrium Effects of Slow Diffusion Controlled Reactions on the Properties of

Explosives, M. van Thiel and F. H. Ree, USA

Computation of a Diverging Comp-B Detonation, B. G. Bukiet, USA

A Theoretical Analysis of the Sonic Point Properties in a Plane Detonation Wave, L. Brun

and F. Chaisse, France

Investigations of the Influence of Polymorphous Transformation on the Process of Detonation

of Mixtures Containing HE and Substances Undergoing Transformation,

E. Wlodarczyk, R. Trebinski, W. Trzcinslii, and W. Witkowski, Poland

Examples of Detonation Shock Dynamics for Detonation ‘Wave Spread Applications,

D. S. Stewart and J. B. Bdzil, USA

Application of Whitham’s Shock Dynamics Theory to the Propagation of Divergent

Detonation Waves, B. D. Lamboum and D. C. Swift, UK

Propagation of Detonation Waves from an Impact Region, R. S. Lee, W. C. Tao, and

L. D. Couch, USA

Detonation Wave Propagation in PBXW-I 15, J. W. Forbes, E. R. Lemar, and R. N. Baker,

USA

Non-Steady Flow in a Detonator, Jia Quansheng, Chen Fumei, and Wang Tinzheng, China

(PRC)

.

. A. Titles Index (Continued)

Sy.Pg Title, Authors, Country.

9.0822

9.0831

9.0842

9.0853

9.0857

9.0868

90869

9.0879

9.0886. 0

9.0897

.9.0906

9.0918

9.0925

9.0933

9.0939

9.0947

9.0953

9.0962

9.0972

Polysulfone SIP Gage for Flying Plate Explosive Components, T. W. Warren and

R. R. Weinmaster, USA

The Effects of Inert Walls on the Velocity of Detonation in EDC35, an Insensitive High

Explosive, G. Eden and R. A. Belcher, UK

Experimental and Numerical Study of Oblique Interactions of Detonation Waves with

Explosive/Solid Material Interfaces, J. Aveille, N. Canon, J. Vacellier, and J. M. Servas,

France

Experimental and Numerical Study of Comer-Turning Detonation, A. W. Gibb, Canada

The Initiation of Fast Decomposition in Solid Explosives by Fracture, Plastic Flow, Friction,

and Collapsing Voids, M. M. Chaudhri, UK

Characterization of Defect Microstmcture in High Explosives Single Cxystals by Synchrotrons

X-Ray Tomography, W. C. Tao and J. H. Kinney, USA

Cavity Collapse in a Heterogeneous Commercial Explosive, N. K. Boume and J. E. Field,

UK

Response of Composite Propellants to Shock Loading, Bai Chunhua and Ding Jing, China

(PRC)

Deformation and Explosive Properties of HMX Powders and Polymer Bonded Explosives,

J. E. Field, M. A. Parry, S. J. P. Palmer, and J. M. Huntley, UK

Physical and Chemical Nature of Hot Spots in TATB and HMX, J. Sharma, B. C. Beard,

J. Forbes, C. S. Coffey, and V. M. Boyle, USA

Hot Spot Formation in a Collapsing Void of Condensed-Phase, Energetic Material,

P. B. Butler, J. Kang, and M. R. Baer, USA

Broad Bandwidth Study of the Topography of the Fracture Surfaces of Explosives,

M. Y. D. Lanzerotti, J. J. Pinto, and A. Wolfe, USA

Effects of Microballoon Concentration on the Detonation Characteristics of

Nitromethane-PMMA Mixtures, H. N. Presles, J. Campos, O. Heuze, and P. Bauer, France

Detonation Characteristics of Dense Gaseous Explosive Mixtures, P. Bauer, M. Dunand, H.

N. Presles, and O. Heuze, France

Detonation Temperature of Some Liquid and Solid Explosives, Y. Kate, N. Men, H. Sakai,

T. Sakurai, and T. Hikita, Japan‘,

The Studying of Detonation Temperawres of Solid High Explosives, Shi Huisheng,

Han Chengbang, Kang Shufang, and Huang Lihong, China (PRC)

Free-Expansion Experiments and Modeling in Detonation: Chemistry and Hydrodynamics on

a Laboratow Scale, N. R. Greiner and N. Blais, USA

Detonation Products of Less Sensitive High Explosives Formed Under Different Pressures of

Argon and in Vacuum, F. Volk and F. Schedlbauer, Germany

Explosive Potential of Carbohydrate-Metal Composites, A. J. Tulis, J. L. Austing,

W. K. Sumida, D. E. Baker, and D. J. Hrdina, USA

●



9.0987

9.0995

9.1008

9.1014

9.1019

9.1027

9.1037

9.1047

9.1052

, 9.1060

9.1070

9.

9.

076

084

9.1100

9.11109.1118

9.1131

9.1140

9.1151

9,1162

A Review of Paramagnetic Resonance Products in Condensed Phase Energetic Materials,

M. D. Pace, USA

Properties of Bis(2 2, 2-Trinitroethyl-N-Nitro) Ethylenediamine and Formulations Thereof.

Dong Haishan, China (PRC)

Use of Oxynitrotriazole to Prepare an Insensitive High Explosive, A. Becuwe and A. Declos,

France

Effects of Binder Concentration on the Properties of Plastic-Bonded Explosives, R. D. Steele,

L. A. Stretz, G. W. Taylor, and T. Rivera, USA

Chemistry of Nitromethane at Very High Pressure, S. F, Agnew, B. L Swanson, J. Kenney,

and I. Kenney, USA

Decomposition Mechanisms and Chemical Sensitization in Nitro, Nitramine, and Nitrate

Explosives, M. D. Cook and P. J. Haskins, UK

Decomposition of Energetic Materials on the Drop-Weight-Impact Machine, G. A. Buntain,

T. L. McKinney, T. Rivera, and G. W. Taylor, USA

Behavior of an Unreacted Composite Explosive on Low Velocity Impact, C. Loupias and

A. Fanget, France

Response of Rocket Propellants to Projectile Impact, S. Y. Ho, Australia

Characterization of Booster-Rocket Propellants and Their Simulants, L. J. Weirick, USA

Experimental Study and Numerical Modeling of Thermal Initiation and Combustion of High

Heterogeneous Explosives, C. Castille, D. Bainville, P. Reynier, and R. Belmas, France

Electrostatic Sensitivity Testing of Explosives at Los Alamos, T. E. Larson, P. Dimas, and

C. E. Hannaford, USA

Molecule-Surface Collision Induced Excitation and Dissociation: n, i-C~F7N0, CcF~NO,

2-Methyl, 5-Vinyl Tetrazole and C(NO,), with MgO(100) Surfaces at E,na~a, S 7.5eV, E.

Kolodny, P. S. Powers, L. Iwata, H. Reisler, C. Wittig, L B. Mishra, and C. Capellos, USA

Initiation and Propagation in Primary Explosives, P. M. Dickson, M. A. Parry, and

J. E. Field, UK

Prompt Detonation of Secondary Explosives by Laser, D. L. Paisley, USA

Laser Initiation of Secondaxy Explosives, A. M. Renlund, P. L. Stanton, and W. M. Trott,

USA“,

Intense Electron Beam Detonation of TATB Explosives, D. Demske, N, Brazen, W. E.

Farley, S. Miller, and R. Wames, USA

Time-Resolved Mass Spectrometry Technique for Studying Fast Transient CHNO Explosive

Decomposition Kinetics, R. D. Skocypec and K. L. Erickson, USA

Laser Ignition of Explosives: Raman Spectroscopy of the Ignition Zone, H. Nilsson and

H. &tmark, Sweden

The Effect of the Pentafluorothio (SF~) Group on the Properties of Explosive Nitro

Compounds: New SFj Explosives, M. E. Sitzman and D. L. Omellas, USA

.

. I

.

34

A. Titles index (Continued)


9.1170

9.1185

9.1193

9.1199

9.1217

9.1224

9.1233

9.1243

9.1253

, 9.1260

9,1271

9.1276

9.1284

9.1293

9.1310

9.1322

9.1333

9.1351

9.1360

Chemistry of Detonation Soot: Diamonds, Graphite, and Volatiles, N. R. Greiner and

R. Hermes, USA

Molecular Models for Explosives: Applications to NTO, J. P. Ritchie, and E. M. Kober,

USA

Reaction and Diffusion in Detonation, N. J. B, Green, M. J. Pilling, and S. H. Robertson, UK

A Thermochemical Model for Shock-Induced Chemical Reactions in Porous Solids: Analogs

and Contrasts to Detonation, M. B. Boslough, USA

Reactive Modeling in Shock Initiation of Heterogeneous Explosives, M. Quidot and J. Groux,

France

Reactive Flo\v Analysis and Its Applications, G. A. Leiper and D. L. Kennedy, UK and

Australia

Physical Evidence of Different Chemical Reactions in Explosives as a Function of Stress,

T. P. Liddiard, J. W. Forbes, and D. Price, USA

Towards Developing the Capability to Predict the Hazard Response of Energetic Materials

Subjected to Impact, C. S. Coffey, D. F. DeVost, and D. L. Woody, USA

“Frozen Hot Spots” in Shocked EDC35, an Insensitive High Explosive, G. Eden,

R. A. Be[cher, M. 1. Andrew, and W. R. Marlow, UK

Deformation and Shock Loading Studies on Single Crystals of Ammonium Perchlorate

Relating to Hot Spots, H. W. Sandusky, B. C. Glancy, D. W. Carlson, W. L. Elban, and

R. W. Armstrong, USA

The Influence of Grain Morphology on the Behavior of Explosives, S. Dufort, H. Cherin, and

P. Gohar, France

Role of Adiabatic Shear Bands in Initiation of Explosives by Drop-Weight Impact,

V. Krishna Mohan, V. C. Jyothi Bhasu, and J. E. Field, UK

Gap Tests as a Method of Discriminating Shock Sensitivity, S. A. Aubert, G. H. Parsons,

J. G. Glenn, and J. L. Thoreen, USA

Shock Sensitivity of Damaged Energetic Materials, H. P. Richter, L. R. Boyer, K. J. Graham,

A. H. Lepie, and N. G. Zwierzchowski, USA

Burning Rates of Two Cast Nitramine Explosives Using a Hybrid Closed Bomb-Strand

Burner, W. C. Tao, M. S. Costantino, and D. L. Omellas: USA “

Explosiveness and Shock-Induced Deflagration Studies of Large Confined Explosive Charges,

P. J. Hubbard and R. Tomlinson, UK

Initiation and Detonation Measurements on Liquid Nitric Oxide, G. L. Schott, W. C. Davis,

and W. C. Chiles, USA

Mechanisms of Detonation and Failure in Weak Chemically Sensitized Mining Safety

Explosives, M. Kennedy and I. D. Kern, UK

Experimental Studies on the Detonation of an Explosive by Multi-Point Initiation, Yu Jun.

Fu Xinghai, and Zhang Guanren, China (PRC)



9.1364

9.1371

9,1378

9.1385

9.1404

9.1416

9.1427

9.1441

9.1451

9.1460

9.1480

9.1489

9.1510

9.1529

9,1543

Detonation Properties of Explosive Foams, C. J. Anderson, K. Von Rosen, A. W. Gibb, and

I. O. Moen, Canada

F.P.I. Velocimetv Techniques Applied to Various Problems in Detonics, P. Gimenez,

J. P. Bedoch, C. Saint-Martin, G. Baudin, and Y. de Longueville, France

Detonation Product Equation of State for Baratol, J. W. Kury and R. D. Breithaupt, USA

Design and Development of Precision Linear Shaped Charges, M. G. Vigil, USA

Jet Initiation Mechanisms and Sensitivities of Covered Explosives, M. Chick, T. J. Bussell,

R. B. Frey, and A. Bines, Australia and USA

Initiation Phenomena with Shaped Charge Jets, M. Held, Germany

Spherical Projectile Impact on Explosives, E. N. Fenn and J. B. Ramsay, USA

Projectile Impact Initiation of Explosive Charges, M. D. Cook, P. J. Haskins, and

H. R. James, UK

Correlation of Explosive Sensitivity to Compressional Inputs, M. Komhauser, USA

Sensitivity of Several Explosives to Ignition in the Launch Environment, J. Starkenberg,

D. L. McFadden, D. L. Pilarslci, K. J. Benjamin, V. M. Boyle, and O. R. Lyman, USA

Study of Explosive Shell Fillings with Defects in Simulated Gun Launch Conditions,

C. Belanger, Canada

A Computational Assessment of the Role of Shielding in Preventing the Sympathetic

Detonation of Munitions, J. Starkenberg, T. M. Dorsey, K. J. Benjamin, and A. L. Arbuckle.

USA

Output Measurements and Modeling of HNS Mild Detonating Fuse, R. G. Jungst and

M. E. Kipp, USA

Detonator Response Measurements with a Standardized Piezoelectric Polymer (PVDF) Gauge.

L. M. Moore, R. A. Graham, R. P. Reed. and L. M. Lee, USA

Indexes for the Proceedings of the Symposia (International) on Detonation— 1951 through

1985, S. L. Crane, W. E. Deal, J. B. Ramsay, and B. E. Takala, USA

.

.

,

36.

B, Topic Phrase IndexAlphabetic

Subject Sy.Pg Subject sy.Pg

1DUCT model of HMX porous bed response 9.0280

2D axisymmetric shock initiation 9.0077~DUCT model of HMX porous bed response 9.0280

Abel co-volumes, computed velocity 2.0237

Abel EOS, hard-sphere gas model, low density 2.0406

Abel EOS, limits in homogeneous explosives 4.0190

Abel EOS, P(V-a) = Rt, curvature effects 1.0094

Abel EOS, simplified Van der Waals’, Cook’s 1.0072

ABH, detonation properties, carbon EOS 8.0528

Absorption spectroscopy, shocked benzene 9.0190

Accelerated combustion in DDT 9.0259

Acceleration wave speeds, PMMA, calculated 5.0589Acceptor explosive pressure histories 8.1144

Accident scenario simulations 8.0211Accident scenario, tank cars of liquid HE 6.0116

Accumulation mechanism for polyatomic molecules9.0724Acetylene-Oz mixtures, D vs calculationsAcetylene-Oz mixtures

Acoustic & optical phonon modesAcoustic approximation, CJ pressure talc.Acoustic approximation, CJ detonationAcoustic approximation for detonation gasesAcoustic impedance, shock transmission

Activation energies, NM parametersActivation energies, steady flowActivation energies, time-to-explosion plotsActivation energy from time-to-explosionADDF, liquid HE, characterizationAdditive density, diameter effects in NMAdditives in RDX/TNT, asbestos, alumina, etc.Adiabatic & Hugoniot curves for mixed phasesAdiabatic collapse, bubbles to hot spotsAdiabatic compression of gases, sensitivityAdiabatic curves, theoretical explosivesAdiabatic elastic moduli of PETN

Adiabatic expansion, detonation productsAdiabatic furnace, dynamite packaging hazardAdiabatic gamma = 3, flow to rigid piston

Adiabatic gamma, predictedAdiabatic gamma, sensitivity to molecular props.Adiabatic shear bands, role in initiationAdiabats in mixed phase, compressibility

2.01982.02569.02352.03944.05239.0560

2.06298.08566.04068.11159.02286.04677.0583

5.04654.02487.0373

7.00076.0553

6.03968.06027.00433.0207

7.06469.05139.12764.0250

ADNBF, shock sensitivity, phys., them. properties 9.0560ADNBF, shock sensitivity 9.0561

ADNT, eutectic composite explosive 7.0801

ADNT performance 9.0478

Aerating explosive gelatine, low-v detonation 2.0582

AFATL 8-inch gap test 91284

AFX-902 performanceAggregate reactivityAir bubble effect, sensitizing nitroglycerinAir-chambers probe, spherical detonation

Air gap effect, initiator & main charge, modelAir gap effect, propagating in cast TNT

Air gap sensitivity test

Air gap sensitivity vs loading density, tetrylAir-match points, Deal’s

Air mixture, calculated shock parametersAir-reaction products interface, P VS upAir shock pressures from donor charges, gap

Air shocks, camera records

Air shocks in air gap (peripheral)Air shocks, sympathetic detonationAir shocks, camera recordsAir vs vacuum, effects of AP sensitivityAir-compression & deformation, HE sensitivity

Airblast effects, prediction from shell modelAirblast effects, reactively cased HEAirblast effects, shock pressure variationAl(C10~3/HMX formulations, cylinder testsA1lO, formed as productALEX 20 & 32, BKW model & performance data

Alien, 2D Lagrangian model, initiationAliphatic compounds, OB/1 00, sensitivity testAllison polarization, shock-induced signalsAlumina effect in RDX/TNTAluminized ANFO, aquarium tests

Aluminized blasting agents, characterizationAluminized explosives, performanceAluminized HE, electric spark initiationAluminized HE, expansion workAluminized HE, for underwater bombs

Aluminized HE, low brisance, high blastAluminized HE, vs perfluorinated HEAluminized HMX, DDT studiesAluminum, 606

Aluminum, 606Aluminum, 606Aluminum, 606Aluminum, 606Aluminum, 606

9.04789.02463.045j

5.00328.0399

8.04091.00242.06314.0063

3.03893.03863.0794I .0009

8.10693.0531

3.03904.03599.14605.04918.02076.07775.01374.01683.0731

8.03993.06775.03875,04657.1016

6.07349.04783.07066.05471.0111

2.07337.0949

70119, cone. effect, ITMfPMMA/Al 6.0129, detonation performance effect 8.1004, effect on wave propagation 4.029j

>endothermic effect at CJ plane 2.0736

, exploding foils, initiation studies 6.0654

, inclusions, incr. shock effects 4.0393

Aluminum, 6061, preheat, preshock, P-V-E data 4.0213Aluminum, 6061, shock wave photo 4.0570

Aluminum, 6061, span from oblique shock waves 3.0253

Aluminum Comp B, effect on velocity 6.0510Aluminum-copper composites, shock loading 6.0151

37

B. Topic Phrase Index (Continued)


.

.

Aluminum particle reaction, underwater explosion 9.0641Aluminum silicofluoride, light enhancementAMATEX 20, diameter-effect parametersAMATEX 20, particle velocities, Lagrange gauge

AMATOL 60/40, curvature effect on shock waveAMATOL, plate dent and cylinder test data

AMATOL, wave shape studies, r/DAmine nitrate (aq.), Threshold v, bum rateAMMO, time to explosionAmmonia effects, cobalt amine azideArnmonia-nitromethane complex calculationsAmmonit, booster study, critical diam & mass

Ammonium dynamite, critical pressure/densityAmplitude-time dependence for golno goAN/ADNT mixes, sensitivity of eutectics

AN/Al, v-D curves, wave shape vs D, kineticsAN-based HE, very small reaction zone lengthAN, detonation velocity & pressureAN, effect in RDX/TNT

AN emulsion HE, D vs densityAN, emulsion HE with 70%AN, eutectics

AN, experimental vs computed HugoniotsAFUI-IMTA, limit data, diffusion effectsAN, improved performance, cosolidificationAN, sensitivity, cavitation effectAN/TNM, BK W model & performance dataAN/TNT/Al, axial initiation vs boosterAN/TNT, density, D, cd, P

Andersen-Parlin EOS, harmonic oscillator

ANFO, aluminized, aquarium testsANFO, axial fuse initiation vs normal booster

ANFO, bubble energy, underwater expansion

ANFO, calculated blasting performanceANFO, chemistry of external plasmas

ANFO, critical density, diameter effectANFO, density, cd, D, experimental pressureANFO, explosive performance characterizedANFO, lateral shock pressure measurements

ANFO, nonideal detonationANFO, pneumatically loaded, double pipe

ANFO, self-luminosity photos, Kerr cellANFO-type booster, propertiesANFOAL, bubble energy, underwater expansionAngle of expansion, calculated for TNTAngular distribution of detonator impulseAntimony, Hugoniot data

Anvil, Al, thermal decomposition, confined HEAnvil, sensitivity test, low-velocity impact

AP/Al/NC propellant, card gitp sensitivity

AP. DDT studies

3.08336.06477.1072

1.00997.0550

2.05036.01199.02283.0054

9.10274.0435

4.0185

3.07987.0801

2.07338.09939.05605.0465

9.05739.0621

7.0801

6.07734.01846.04397.03733.07314.01563.0376

2.0406

7.10164.0156

6.0546

8.09873.01864.01793.03816.07294.0095

3.03098.0390

6.04244.0435

6.05462.04513.03006.06026.02144.0473

3.08227.0151

AP, diameter effect, reaction zone thickrtess

AP, diameter effect, D vs l/d, limit dataAP, growth to detonation, interferometryAP, Hugoniot curve with Rayleigh lineAP-loaded EBW initiation

AP, mechanical properties, drop weightAP, performance modelAP, propellants, properties, parametersAP, shock initiation of low-density pressingsAP, shock loadingAP, single crystals, shock loading

AP, sympathetic detonation by NQAP, time to explosionAquarium gap test, damaged energetic materialAquarium technique, detonation pressure

Aquarium technique, P, streak camera traceAquarium test, aluminized ANFOAquarium test, ANFO, nonideal detonationAquarium test, detonation pressure in EA

Aquarium test, detonation performanceAquarium test, lateral shock pressure

Aquarium test, mapping failure wavesAquarium test, one to several hundred kbar PAquarium test, shock pressure < detontttionAquarium test, subignition reactionsAquarium test, TATB/HMXAquarium test, X-0233, detonation behaviorAqueous emulsion HEsArc experiment

Area of shock loading, initiation threshold

Argon, thermodynamic propertiesAromatic nitro compounds, sensitivity & OB

ARP propellant, detonability in DDT study

Arrhenius constants, NQ, TATB, HMX, PETNArrhenius kinetics, HNS

Arrhenius kinetics, initiation & propagationArrhenius one-step unimolecular reactionArrhenius param~ters, thermal decomposition

Arrhenius plots, intermediate radical growthArrhenius rate, shock-strength modifiedArrhenius to non-Arrhenius kinetics

ktificial viscosity calculation, underwaterARTOO, 2D Lagrangian propagation code

Asbestos effect in RDX/TNTASM probe, particle velocities, test setupASM probe, recordAtmosphere effect, circuit-recorded voltageAttenuating shock waves, elastoplastic effect

Attenuator Hugoniot and rarefaction locus

Autoignition after travel, ZeldovichAxial cume vs reaction zone vs diameter

4.0097

4.01834.0584

4.01884.0452

8.06427.05177.01914.03599.08799.12606.01739.0228

9.12955.0059

3.03827.1016

3.03157.0549

7,08014.0092

5,0115

3.03573.01528.07277.05738.09799.05459.0730

9.0066

8.0815

3.07003.0642

8,00439.0209

6.04059.02197.00917,00807.03859.0235

5.05979.0209

5,04656.06375.04512.01424.0277

3.0501

1,00498.0159

.

.

*38

Subject


Sy.Pg Subject sy.Pg

I

Axial initiation, multicomponent HE chargesAxial initiation vs normal booster initiationAxisymmetric detonation wave velocitiesAxisymrnetric electromagnetic probe (ASM)Axisymmetric explosion analysis code

Axisymmetric flow, spherical shock, slurryAxisymmetric impact, propellants D and E

Axisymmetric wave propagating in a half-spaceAzide, time to explosionAzides, detonation velocity, size effects

Azides, explosive, electrical initiationAzides, photolysis & thermolysis (N3 ,exciton)

B 2141, diverging detonationsB 2141, flyer plate, critical surface areaB 2142, ballistic classificationB 2142, diverging detonationsB 2161, (HMX/AP/A1), Mach phenomenaB 2161, ballistic classificationB 2169, (PETN), Mach phenomena studyB 2174, ballistic classificationB 2174, [HMX/AP/Pb(N03)z], Mach study

B 2190, (PETN/HTPB), Mach phenomenaB 2191, [HMX/AP/Pb(NO,)z], Mach studyB 2192, [HMX/AP/Pb@J03) #%], Mach study

B 2214, propertiesB 3003, (1-WCWNC-NGL), Mach phenomenaBall-bearing impact sensitivity testBall propellant data, four porosity levels

Ball propellant, DDT studies

4.01564.01568.01555.04473.0226

8.0168

8.02855.0493

9.02282.0561

6.0390

3.08437.0408

7.03208.06267.0408

8.0431

8.06268.04318.06268.04318.04318.04318.04319.1008

8.04313.0001

9.03639.0354

Ball propellants, compaction, single-, double-based 9.0341

Ballistic capacity vs shaped charge 8.0630Ballistic impact chamber (BIC) test 9.1243Ballistic mortar test, MN sensitivity 5.0268Ballistite transition, DDT in AP 7.0156Balloon test, underwater HE detonation 9.0626Baratol/Al wave diagrams,manganin gauge study 6.0631

Baratol/Comp B plane wave shaper, resonation 4.0426Baratol, density, shock & particle velocities 4.0245Baratol, detonation product EOS 9.1378Baratol, diameter-effect parameters 6.0647Baratol, free-surface motion, precursor waves 4.0579Baratol Hugoniot 9.0379Baratol, in modified gap test 7.0279Baratol, overdriven shocked states 5.0533Baratol, P-t profile, sulfur conductivity 3.0241Bamtol, perpendicular driver, aluminum, x ray 6.0602Baratol, plate impact pressure profiles 3.0246Baratol products EOS 9.1378Baratol~T, density, D, cd, P 3.0376Baratol, UK, wave shapes in rods 9.0784Baratol, wave shape studies, r/D 2.0503

Baratol, wax gap testBartlett’s test, least-squares fitsBase gap effect on Comp B, TNT sensitivityBDNPM3DNPAF concentration, effects on HEBenzene, shocked, absorption spectroscopy

Benzene/TNM, BKW model & performance data

Benzofuroxans, substituted, shock sensitivityBenzoyl peroxide, thermal decomposition

Berger’s vectorBeryllium, elastic-plastic behaviour

Beryllium wall, effect on D of EDC35

BH- 1, (RDX+), detonation parametersBH-1, Hugoniots, velocity/pressure dataBichromator, temperature, Raman bandBimetallic & metal semiconductors, shockedBimetallic ems generation in shocks

Bimodal formulationsBimodal velocity distribution, ANFOBimolecular decomposition

Binary mixtures, melting points (eutectics)Binder concentration, effect on PBX propertiesBinder, effect on explosivenessBinder, improved inert, detonation effectsBiplanar observation, detonative centers

Birch’s isotherm

Bis- & tris-difluoramino perfluorobutaneBis-difluoroamino alkanes, critical diameterBis-difluoroarnirto alkanes, shock initiationBis(2,2,2,-rinitroethy l(-N-nitro) ethylenediamineBismuth phase transition, electrical junction

BKW calculations and cylinder test resultsBKW calculations, detonation performanceBKW calculations, emulsion HE, D vs densityBKW calculations for RDX/TNT mixturesBKW code, spherical explosions underwater

BKW EOS, carbon talc in detonation products

BKW EOS, QUATUOR codeBKW eqtition, EOS for detonation gases

BKW-HOM EOS VS data, lD calib., Comp B-3BKW model, HMX/AP/Al propellantBKW model, hot-spot temperature

BKW model, postdetonation behaviorBlackbody radiation in liquid HEBlackbody spectral intensities, 3000-6000 KBlast wave, 500-kg emulsion HE testBlast waves in liquids, initial stagesBlasting caps, stresses generatedBlasting performance, commercial explosives

BO- 1, HMX explosive, resonation effectBoltzman EOS, gaseous HEsBoltzmann EOS, QUATUOR code

1.0023

3.03357.09149.10149.0190

3.07289.0566

7.0027

9.00585.0467

9.0831

8.0440

8.00837.10105.04035,04039.00183.03256.03086.047(J9.10148.10357.05608.03309.0050

7.09405.0089

5.02379.09956.01518.11373.07259,05736.05175.06034.0599

8.0763

1.0073

5.0008

7.062070348706467.07591.00159.06216.05023.0285

8.09858.00939.09338.0764

39



Bohzmann vibrational temperatures, calculated

Bomb tests, TNT in DDT studyBond polarity and decompositionBond scission, excited electronic stateBond scission reactions, unimolecularBooster HE, emp velocity gauges

Booster properties, critical diameter vs massBooster sensitivity test setup, scaling testsBooster studies, TATB initiation, model

Boosting effect on steady detonation velocityBorehole, charge with air shock ahead of frontBoron nitride, polymorphic transformation, deton.Boundary conditions corresponding to pistonBoundary conditions, strong point explosion

Boundary rarefaction effects, release wave

BOW wave, desensitizing effectBo\v wave, effects on detonation

Bow wave shock initiationBrass wall, effect on EDC35 detonation velocityBrazilian test & laser speckle, tensile strength

Brazilian test geometry, drop weight testBridgewire (Cu & Nichrome) initiation, RDX

Brightness temperature, mean, liquid HEsBrightness temperature, nitromethaneBrightness temperature, nitromethane flyersBrightness temperature, overdriven NMBri.mnce defined, aluminized explosivesBrisance factors in donorsBrittle-type fractures in steel platesBruceton method described, 50’% firing

Bruceton method, impact velocity, 50% probable

Bruceton test, drop-weight impact test

Bruceton test, HE-wax sensitivity

Bruceton-type direct-contact sensitivity test

BTF, CJ properties, oxygen balanceBTF, experimental & calculated CJ parametersBTF performanceBTFMA, liquid HE, characterizationBTNEN, adiabats calculated for energy release

BTNEN, impact sensitivity, critical tempBTX, high-temperature EBW detonator explosiveBubble & spike interface, 2 fluidsBubble effects, cavity initiation, gap test

Bubble effects, compressive heatingBubble effects, LVD studyBubble effects, shock wave interaction, NMBubble effects, underwater explosionsBubble energies, undenvater detonations

Bubble energy, underwater HEsBubble pressure vs time, liquid IHE modelBubble pulsation energy, fraction of original

8.0691

3.06377.00697.00938.08278.0447

4.04352.06238.1045

6.06428.10709.0766

3.05416.0591

3.02678.03183.0802

9.14049.08319.0886

8.0635

3.00887.07627,07687.10028.04272.07342.06281.0037

2.0622

6.0682

3.00017.0337

4.0407

8.05476.07139.04786.04673.07403.00696.04604.03052.06767.00095.00863.04891.00086.0540

9.06336.01216.0559

Bubbles & voids, initiation by

Buckingham potential, intermolecular energyBuckingham potential, modified for EOS modelBuckingham-Kees potentialBuildup to detonation, smear camera, RDX/AlBuildup to detonation, impacted HMX, TATB

Bullet impact, results, sensitivenessBullet impact, sensitit~eness vs gap testBullet impact, single-cxystal sensitivity

Bullet impact, test, single-crystal sensitivityBullet impact, test, setupBullet impact, test, TATB/HMX mixtures

Bum fraction in Eulerian coordinatesBum model, 1D SDT of RDX, mesh size, P

Bum model, compressible solids & gasesBum model, explicit hot spotsBum model, hydrodynamic motion

Bum model, nondetonative, ventingBum model, slurries and emulsions

Bum pressure in undenvater & gap tests

Bum probability vs impact velocity, ammoBum rate anomalies, Comp B, TNT, M30A 1

Bum rate parameters vs pressure exponentBum rate vs pressure, DDTBum rates at higher pressuresBum rates of solid HE, sensitivenessBum rates, nitramines, high pressureBurning of secondary HE by convectionBurning, superfast regression

Burning tube test data, RARDE, explosiveness

Burning-front velocity vs initial temperature

Bursting pressure ratio vs velocity

Butane diol dinitrate, sensitiveness

Butane isomers, failure diam & sensitivity

Butylene, sensitiveness, Q, mC.E.E. 2D model, nonideal detonationsC-NOl, time-to explosionCable calibration $ummary, pins, delay systemCable delay timing system, pin recordsCable delay timing film, velocity data filmCalcule ballistique, simpler predictionCalibrating sensitivity tests, laserCalibration curves, shock tube

Calibration, global, HE reaction zoneCalorimetry, detonation, AN/ADNTCalorimetry, mixing tests, HEs, modelCamera record, inverse multistreakCamera record, laser initiation, lead azide

Camera record, resonation, divergent wavesCamera record, streak, ChineseCap sensitivity of emulsion HEs

9.0857

2.04377,0716

9.05133.07088.03462,0703

?.06442.04712.047 I6.06847.05723.07249.12247.0234

8.00525.04877.0175

8.09854.0494

6.068970898

5,0191

3.06353.00782.06519.13103.00777.0168

7.1040

9.1070

2.0223

2,0699

5.0089

2.06487.06959.02282.04412.04412.04457.0953

8.04733.00309 o~j2

7.08078.101970753

7.0738-104287.074990585

.


Subject Sy.Pg Subject sy,Pg

Capacitor discharge testing of HEsCapture & analysis of detonation productsCarbamates & dicarbamates, SF~Carbohydrate-metal composites, potential as HEs

Carbon behind shock frontCarbon condensation

Carbon, condensation effectsCarbon condensation, in shocked benzene

Carbon EOSCarbon, Hugoniot data, graphite and diamondCarbon clusters and melt line, soot examinationCarbon monoxide/02, normal detonation waveCarbon, phase changes, effect on detonationCarbon resistor pressure gauge

Carbon tetrachloride, NM diluent

Card gap test, SPHF plate shock pressure

Card gap test, setupCard gap test, delayed detonation

Card gap test, low-pressure, long durationCamahan-Starling (CS) EOS, QUATUOR codeCamahan-Starling (CS) hard-sphere EOSCarrel & Holt particle-to-particle stressCARS data, liquid N2 & NMCase effect on airblast of PETNiTNT

. Case, expansion model, CYCLONE codeCase, expansion modelCase, penetration effect, modelsCased charges, airblast effectCased charges, fragment impact responseCast TNT, reaction extent historyCast-cured PBX, modeling of wedge testsCasting EMP velocity gauges in explosive

Casting, pressing, and machining HE chargesCAT finite-element thermal ignition codeCavitated liquid IHE model, DDT from bum rate

Cavitation effect on sensitivity of liquid HE

Cavitation in solids & liquids, fracturingCavitation model of low-velocity detonatio~Cavitation threshold as limiting factor in HECavity collapse ignition, Comp BCavity collapse in energetic materials

Cavity collapse in emulsion HEsCH-6, small-scale gap testChain initiation, radicals in unreacted gas

Channel effect, precompressed explosiveChannel plate detonative centering

Characteristics method, NIP codeCharacterization, booster-rocket propellants

.

8

Charge

ChargeCharge

diameter, detonation wave curvediameter effect, detonation velocitydiameter, velocity dependence in LVD

9.10769.06219.11629.0972

9.0396

9.0417

9.07439.01909.04438.05529.04171.0045

9.04259.05376.0133

3.0150

3.08247.0265

8.02288.07648.08059.03639.01806.07773.02267.08347.02738.02078.02629.02529.12177.1072

2.01199.10706.0115

7.0373

3.08055.00814.04138.10808.00689.08699.00982.02298.10698.03304.0538

9.10607.0592

8.09065.0086

Charge length effect, l/d <3, I/d = 18.5, TNTCharge preparation, detonation velocity testsCharge radius, steady velocity dependenceCharge-separation hypothesis, wave fground

Charge- size effect on plate dent depthCHD-3, 1D Lagrange model, Chinese

Chemical aspects of detonationChemical composition effect on performanceChemical decomposition model, confined HEChemical decomposition model, Lagrange gaugesChemical energy release equation, ID modelChemical energy, unloading rate effectChemical equilibrium codeChemical ionization mass spectrometry (CIMS)Chemical kinetics, C.E.E. 2D model

Chemical kinetics in detonation

Chemical reaction, model, shock wave initiationChemical reaction, rate, PBX 9404 vs LX-17Chemical reaction, result of fractureChemical reaction, shocked HNSChemical reactiotitransverse waves, dark wave

Chemically sensitized mining safety HEsChemico-acoustic interactionsChemionization, source of plasma luminosityChemistry in free expansion of HE productsChemis~, NM, high pressureChemistry of detonation sootChemistry of underwater HE detonationsChemistry, thermal explosionCHEMKIN chemical kinetics, void collapse talc.

CHEQ, chemical equilibrium modelChicanery, retarded detonation

Chinese detonation research, survey

CHNO HE decomposition kineticsCID, collision-induced dissociation, experiments

Cine-microscope, new, detonation phenomenaCineradiography, flash x ray (100,000 fps)CissoidiY detonation wave, vertex, Mach waveCJ adiabat, kinetic energy of water, bubblesCJ adiabat, P-uP for HBX-ICJ condition, axial flow, spherical frontCJ condition, calculated, low-density HE systemsCJ condition, cylindrical or spherical flowCJ condition, hydrodynamical studiesCJ condition, initial conditions for flowCJ condition, point of complete reaction

CJ deflagmtion, shock = CJ detonationCJ deflagration, wave model, DDT studyCJ detonation, acceleration, no conductionCJ detonation, pressure, 2ND and CJ modelsCJ equation derived, precompression effects

2.0504

2.01196.0642

2.01422.0752

8.00941.00436.07107,00567,04983.06147.0857

9.04618.07257,0695

4.0075

6.03718.09538.0243

8.00156.04T49.1351902193.0187

9.09539,1019

9.11709.06269.02289.09068.05026.0225

7.0795

9 lIW9.1084

2.01687.0986

4.01356.05615,05?3801685.00564.0078

I 01076.060310055

3.07936.02387.0634

7.05315,0069

-JI



CJ expansion adiabat, from cylinder test dataCJ gamma detlned, adiabat for energy release

CJ hypothesis, D = u + cCJ isentrope & underwater pentolite testsCJ isentropes measured for X2, T2

CJ model, ASM probe pressure dataCJ model, shock amplitude evolutionCJ parameters, (P, t, u, D from TIGER model)CJ parameters, ditta & calculatedCJ parameters, EOS constants, LX-14CJ parameters, polytropic EOS, 2D modelCJ parameters, release isentropes, calculatedCJ particle density effect on CJ performance

CJ particle velocity by EMV gauge

CJ plane, coinciding with combustion wave

CJ plane, conduction zone behindCJ plane, equilibrium, steady stateCJ point, density of solids affects pressureCJ point, shock properties of reaction productsCJ point, temperature, pressureCJ point, velocity measurements, HMX/TNT/inertCJ pressure & reaction zone length measured

CJ pressure & gamma (talc) vs dural dataCJ pressure, calculated: TNT, Comp B, octol, . . .CJ pressure, effect, AWRE EOS determination

CJ pressure, estimated from Jones equationCJ pressure, high-density RDX, TNT, RDX/TNT

CJ pressure, highest in detonation waveCJ pressure, measured in explosives

CJ pressure, new aquarium technique (Chinese)

CJ pressure vs homolog sequence numberCJ products as high-density lattice structureCJ properties, AN- & EDD-loaded HE, modelCJ properties, ~ & Al-loaded explosivesCJ properties, AP, RUBY codeCJ properties, CHNO & CNO explosivesCJ properties, high-carbon CHNO, modelCJ state calculations, BKW modelCJ state calculations, CS hard-sphere EOS

CJ state derivatives, JWL EOS

CJ state, initial state variationCJ state, PBX, inert binder effects, waves

CJ state, RDX, TNT: JCZ EOSC.i state, variation of molecular parametersCJ surface location reaction rate influences

CJ temperatures, five liquid explosivesL.’.ltheory, 1st approximation of D (velocity)

CJ theory, cyanogen, Oz, N2 mixtureCJ theory, failure in liquid & solid HECJ velocity, front, Taylor waveC.f volume bum vs two-phase burn, y vs JWL

~~

7.0646

3.0739

1.00884.00278.07536.06396.03838.09656.07138.06187.05897.10723.07355.04211.00443.01172.02001.01129.03791.00214.00562.03433.03945.00237.06822.03802.03833.03822.03277.07959.0461?.04057.05558.05554.03608.05548.05213.07268.08058.07788.07787.05606.01628.07742.04947.07595.00412.02314.00845.00048.0948

CJ wave, steady state, calculated flowCJ zone length, calculated

Classical detonation wave modelClosed-bomb test results, Comp B

Closed-vessel deflagration, HE + propellantsClosed-bomb strand burner, hybridCluster formation, carbonClusters, carbon & nitrogenCMC probe, composite manganin-constantanCN-stretching mode, NMCOZ laser, ignition of propellants

COZ, test and calculated HugoniotCOZ vs CF: as detonation products

Coal-mining explosives, luminosityCoal-mining explosives, critical detonation P

Coaxial HE conductivity experimentsCobalt amine azides, thermal decompositionCochran-Chan rate constants, PBH-9DCold LX-17, buildupCollapse of cavities in HECollapse of single pore by shock wave

Collapsing void, condensed HE, hot-spot formation

Collapsing voids, initiation of fast decompositionColliding-ball HE impact sensitivity testCollisional energy transfer

Combustion, compressive, granular materialsCombustion data correlated with sensitiveness

Combustion energies, oxides and fluoridesCombustion in a cavity, calculationCombustion model, s~ess wave propagation

Combustion propagation

Combustion wave transformation, high orderCommercial blasting agents, characterizationCommon distance vs shock velocity in wedge testComp “A-5, exploding-foil shock sensitivityComp A, diameter-effect parametersComp A, modified, detonation velocity, ratesComp A-3 Type ‘H, ignition thresholdsComp A-5, sensitivity and explosiveness

Comp B-3,

Comp B-3,Comp B-3,

Comp B-3,Comp B-3,Comp B-3,Comp B-3,Comp B-3,Comp B-3,Comp B-3,Comp B-3,

drop-weight impact test

shock wave decay in Allow-velocity impact ignition

isentropes calibrated from datameasured pressures, four testspulse duration sensitizing effectthermal initiation and growthoblique shocks, perpendicular driveparticle velocities, magnetic probeimpact response, model and testsshock desensitization

Comp B, air Hugoniot and CJ isentropes

7,05049.0806S.04878.02526.01959.13109.07439.07439.00779.01807.02178,05517.09492.05714.05569.03963.00509.01429.01339.08699.05939.09069.08573,00019.10849(32932.06437.09412.06877.02089.10701.00436.07299.12177.09286.06472.01309.14608.0265

3.0006

3.02544.0478

5.00095.00145,0191j.o~go

6,0602606377.0273810578.1076

.

.

.

.



Comp B, Al & LiF effects on acceleration

Comp B/AN, diameter effect, D vs I/d

Comp B and Comp B-4, deflagration, ventingComp B, anomalous bum rate characteristicsComp B, base gap effect on sensitivity

Comp B, BKW model & performance dataComp B, camera record, impact to initiationComp B, card gap (SPHF), P-x curves, ionizingComp B, cased and bare, jet initiationComp B, cavity collapse ignition

Comp B, chemical decomposition models

Comp B, CJ point, CJ isentrope, error ‘%.

Comp B, computation of diverging detonation

Comp B, computation of diverging detonationComp B, conducting zone, electrical effects

Comp B, conductivity profile, pin signalsComp B, conductivity profiles, C precipitationComp B, confined, after firing, deflagrationComp B, comer-turning model, PHERMEXComp B, crystal structure, sensitivenessComp B, cylinder test resultsComp B, density, D, cd, experimental pressure

Comp B, density, shock and particle velocitiesComp B, detonability, propellants & explosivesComp B, detonation-driven plates & cylindersComp B, detonation pressure dataComp B, detonation products, test, calculationsComp B, detonation properties, carbon EOSComp B, detonation pressure profile

Comp B, diameter-effect parameters

Comp B, dural, u=Comp B, dural, UmComp B, dynamic detection of spallingComp B, EMF generated by conduction zoneComp B, energy threshold, P-t plotComp B, eutectic with TNT, strain-free casting

Comp B, exploding-foil shock sensitivityComp B, explosively driven metal, modelComp B, flyer plate critical surface areaComp B, fracture surface topographyComp B, free-surface motion studiesCornp B, gap test results, variable donorComp B, gap test, low pressure, long durationComp B, heat of detonation Q, D, Pc,Comp B, high-vacuum detonationComp B, HugoniotComp B, ignition by air gap compression

Comp B, impact initiation, .30-cal cylinders

Comp B, initiation by metal jet, x-t plots

Comp B, isentropes, KHT vs JWL

Comp B, jet temperatures, IR radiometer

6.0510

4.01827.01757.08987.09143.07283.04233.01528.03188.1080

7.0056

7.0709

9.0743

9.07513.0120

3.01404.05996.02046.04103.06664.0005

3.03774.02453.06394.00237.05318.0581

8.05289.0471

6.06472.03347.05356.04773.01166.0106

2.01197.0928

8.06107.0316

9.09184.05777.02798.02283.07445.05619.03797.0003

2.06127.0352

8.05566.0691

Comp B, low-pressure point on isentrope 3.0389Comp B, low-order wave, resonation, wave exit 3.0833Comp B, low-order explosions after impact 6.0328Comp B, Mach interaction, two waves 4.0142Comp B, measured detonation pressure, aquarium 5.0065Comp B, nondetonative explosionComp B, overdriven detonation waves, EOSComp B, overdriven shocked statesComp B, particle sizes, finite & infinite diameterComp B, particle velocities

Comp B performance

Comp B, physical parameters

Comp B, Plexiglas monitor, shock velocity

Comp B, Pop plots, bum rate modelComp B, pressure time profiles, manganin gaugeComp B, pressure shear ignitionComp B, pulse duration sensitizing effectComp B, radiation & blackbody temperaturesComp B, reaction productsComp B, release wave, boundary rarefactionsComp B, sensitivity vs gap thicknessComp B, shock-induced electrical polarization

Comp B, shocked, thermal film recordComp B, spherical Al shells, velocities

Comp B, stainless steel, interface velocity, modelComp B, sympathetic detonationComp B, transmission of shock waves in Al

Comp B, velocity-diameter curvesComp B, W, Fe, Al, A1-Mg, & Be (model)

Comp B, wax-gap testComp B, x rays of detonationComp B-3, diameter effectComp B-3, pressure data, PHERMEX, u,Comp C, drop weight impact testComp C-3, measured D, 0-60 kpsi

Comp C-4, diam effect, reaction zone thicknessComp C-4, gap test sensitivity

Comp C’-4, growth to detonation, interferometryComp C-4, performanceComp C-4, shock wave decay in AlCompaction, distance vs IYoTMD

Compaction, effects on flame travel, DDTCompaction, heat generation in hot spotsCompaction, porous beds of inerts

7.02484.00475.05332,04797.1072

90478

7.0593

5.00237.0481

6.06259.00035.01917.0879

9.09623,02677.09?0

5.04297.0973605214.0545

3.07901.00907.05897,0796

1.00?38.03229.0197

5.00138,06405,007340097

3.08304.058490478

3.0254

8.093870143

8.09267.0843

Compaction, single-, double-based ball propellants 90341Compaction wave acceleration, granular material 90306Compaction wave, DDT 9.0265Compaction waves, piston-propellant impact 70261Composite explosive, HMX/emulsion 90545Composite emulsion explosives, performance 9,0573Composite HE, Al perchlorates/HMX 5,0137

.43



Composite HE, calculated ignition dataComposite HE, detonation modelComposite HE, higher-energy prospectsComposite HE, low-velocity projectile impactComposite HE, metal acceleration

Composite HEs, underwater performanceComposite manganin-constantan ring probeComposite propellants, response to shock loadingComposition F.209, spherical detonation waveCompressed-gas gun, short-pulse shocksCompressibility, weaker shocks cause reaction

Compression, ramp-induced, shocked propellantsCompression waves, characteristics, shieldingCompression waves, propagating, camera record

Compressional input, correlation to HE sensitivityCompressiveCompressiveCompressiveCompressive

CompressiveCompressiveCompressiveCompressive

Compressive

(hot spot) burning stage, DDTburning, DDT, experiment & theorycombustion, granular materials

heating, cavity collapse, Comp Bheating, ignition model

heating, ignition irnd launchloading of heterogeneous HEsreaction, ball propellants

shock & acceleration (ramp) wavesCondensation shock, centered wave expansionCondensation shocks & weak detonationsCondensation shocks in 1D unsteady flowCondensed carbon yield in detonationCondensed explosives, reactivity

7.04627.0517

9.05549.10478.1018

9.06339.00779.0879

5.00317.0857

2.06298.0962

8.11453.04209.14518.06669.0320

9.0293

8.10807.0003

9.14609.0604

9.03417.0394

2.03082.02952.03009.04079.0246

Condensed HEs, detonating, electrical conductivity 9.0396Condensed-phase detonation, summary of papers 4.0198Condensed-phase reactions, nitric oxide

Condensed phase with cavities, talc initiationCondensed-phase particle conservation equations

Condensed reacting media

Conductance-distance curves, SPHF (card gap)

Conductance, normalized approx, hemi probe

Conduction traces, Comp B and pentoliteConduction zone behind CJ planeConductive (laminar) to convective bumConductive and convective burning, DDT studyConductivity, detonating HEConductivity, in detonating condensed HEConductivity, probe records, SPHF platesConductivity, profiles, electrodes in propane

Conductivity, profiles vs C content, products

Contlned acceptor charges, jet initiation

Confined-charge response to fragments

Contlned charges, 2D metal & gas flow, modelConfined charges, fuel fire, minitrial

Confined charges, steel yoke setup

44

8.0715

2.06899.0363

9.0250

3.0164

4.0596

3.01293.01177.01648.06653.01399.03963.01503.01224.0595

9.1416

7.1048

3.02267.10406,0204

Confined drop hammer test, IHE 7.0965Confined HE, chemical decomposition model 7.0056Confined HE, propagating detonation model 7.1055Confined heating, TATB/HMX mixtures 7,0571Confined TNT charges, final velocities 3.0337Confinement & pressure effects, deflagration 6.0204Confinement effect, failure diameter, PBXW-115 9.0806Confinement effect, SSGT 9.0098Confinement effect, violence, deflagration 9.1322Confinement effects, contact sensitivity 4.0408Confinement effects, EBW initiation 4.0449Confinement effects, energy prediction 8.0176Confinement effects, gap test, discontinuity 3.0805Confinement effects, low-velocity detonation 7.0575Confinement effects, PBX 9502, Mg, Al, PMMA 8.0376Confinement effects, propellants detonating 3.0823Confinement effects, small PETN & TNT charges 2.0768

Confinement effects, subsonic flow, model 6.0368Confinement effects, velocity, ANFO 3.0316Conical implosion generator, Cu & U 5.0548Conservation equations, 1D, spheric symmetry 6.0590Conservation equations, gaseous detonation ?4zbij

Conservation equations, mass, energy, momentum 1.0088

Constantan gauge records, low-order detonation 6.0330Constitutive model, for 2D code DYNA2D 9.0280Constitutive relations, global method calibration 9.0252Contact shock initiation, spherical projectile on HE 9,1427Continuity equation, spherical detonation waveContinuous rate probe, LVD in nitromethaneContinuum mixture model, fhe-grained HNSConvective bum (CB), gas penetrative, DDTConvective burn model, regression rates

Convective bum model, solid propellant cracksConvective burning, explosive powders

Convective combustion, early phase of DDT

Convergent cylindrical shock waves

Converging (sonic) detonation waves

Converging 1D spherical detonationConverging detonation, 2D Lagrangian modelConverging flow driver, planar flyer platesCopper cylinder test, heat of detonationCopper, plane spalling, 1D calculationCopper, radiance ratio & blackbody ratioCordite sensitiveness, gap test scaleCoriolis acceleration, frictional heat

Comer turning & desensitization

Comer-turning data, EDC35 vs U.S. IHEs

Comer-turning data, Comp B, image intensifier

Comer-turning data, PBXW-115Comer-turning data, TATB

Comer turning model, hot spots

1.00937.05779.02096.02507.0164

7.0186

3,0077

9.0329

1.00797.0638

7.06029.12177,08269.0478505676.06922.07028,02479,1224

9.0123

6.0666

9080670624

8.0052

.

.

“

. B. Topic Phrase Index (Continued)


Comer turning, model, PBX 9404 & LX-17

Courant criterion, artificial viscosity

Cover-plate thickness, effect on jet initiationCowan-Fickett data, effective ys, @

CP, DDT calculation of flame, comer turning

CP, DDT, characterizationCP, detonator in flying-plate tests

CP, new explosive, low-voltage detonatorsCrack effect on octol, hot plate & hot wireCritical acceleration for shock growthCritical acceleration, radii of curvatureCritical air gap, tetryl acceptor densi[yCritical air gap, lead azide/tetrylCritical angle for Mach bridge, shocks, foam

Critical barrier thickness, Comp B chargeCritical booster diameter & mass

Critical capacitor voltage, confined chargesCritical conditions, impact initiatiort

Critical conditions, shock initiationCritical diameter, additive density effect, NM

Critical diameter, AN/Al mixturesCritical diameter, AP, sympathetic detonation

.Critical diameter, confined charges of NMCritical diameter, NM-diluent mixtureCritical diameter, threshold for propagation.Critical diameter, wave front shapeCritical energy concept, TNT detonationCritical energy concept, shock initiation

7.04886.0337

9.1404

3.0721

8.0675

7.0865

9.08246.0455

5.02846.0047

6.03871.00252.06266.04897.03544.0435

6.0207

7.03166.0068

7.0583

2.0744

6.01747.06096.01355.02077.07926.00046.0011

Critical ener~ concept, impact on tetryl, Comp B 6.0327

Critical energy concept, initiation behavior 7.0459Critical energy concept, derived from gap test data 8.1136

Critical energy fluence, molecular dynamicsCritical energy fluence, criterion, pressuresCritical energy per unit area, initiationCritical impact criteria, shock initiationCritical impact diameter, thin flyer-plate impactCritical impact velocity, fracture stressCritical impact velocity, vs lengthCritical impact velocity, shotgun facility

Critical jet initiation energyCritical particle velocity, initiation thresholdsCritical shock duration, reaction kineticsCriticai shock initiation energy modelCritical shock intensity, shocked liquid HE

7.07787.0887

9.00667.08579.0066

1.00354.04747.0299

8.10915.02276.01057,0459

3.0820Critical shock, NM, MMAN, TNT, AN, DNT, DNB7.0382Critical shock pressure equations 8.1123Critical surface area, SDT parameter 7.0316Critical temperature for TATB 9.1070Critical temperature scaling, confined HE, DDT 6.0218Critical temperature tests, time to explosion 8.1114Critical thickness of detonation propagation 8.0994

Critical thicknesses for sheet inclusions, NM

Critical transfer charge diameter

Crystal breakup in reaction of solidsCrystal defects, role in forming hot spots

Crystal diameter effects in HEs

Crystal growth, PETN, elastic moduliCrystal melting effect on burning HMXCrystal microstructure & defects

Crystal orientation, incident laser energyCrystal shape effect, PBXCrystal size effects, thermal inititiation of azidesCrystal structure, HMX polymorph sensitivityCi-ystal thickness vs velocity, lead azideCrystallographic data, NQ

Crystals, HE, impact initiationCS EOS, detonation temperature vs density

CTPB and HTPB binders, diameter effects

C’fX- 1, sensitivity and explosivenessCU-CTE junctions, shock wave effect

CuO-Mg, deflagration velocity, electric probe

Curable plastic-bonded HE, CX-84ACurvature, detonation velocity relationCurvature effects, detonation front, HMXCurvature effects, shock wave evolutionCurvature effects, stable detonation wavesCurvature of axis effect, detonation velocityCurvature of detonation front, mining safety H_EsCume fits, five methods, shock velocityCurved-front theory, wave shape vs rate

Curved-front theory, reaction rate, TNT/NANO

Curved-front theory, nonplanar shock wave

Customized explosives, TATB- & HMX-basedCutback experiments, thin flyer-plate experimentsCX-84a, curable plastic-bonded explosiveCyanogen-Oz mixtures, high-temp thermodynamicsCyclic polynitroaliphatic SF~ HECyclone model, transient 2D flowCyclotoi 75/25, free-surface velocityCyc-lotol 75/25 HugoniotCyclotol, BKW model & performance dataCyclotol, cylinder test resultsCyclotol, diameter-effect parametersCyclotol, low-pressure point on isentropeCyclotol, measured detonation pressureCyclotol, underwater shock-to-bum testsCyclotol, wedge test with smear camera recordCyclotol, wedge test with smear camera resultCylinder energy, simpler prediction

Cylinder test, heat of detonationCylinder test, 42 HMX/9 AP/19 A1/30 binderCylinder test, 88 RDX/12 PBHT

4.0391

8.0334

3.07949.1260

9.00986.03965.031 I9.12609.01729,0083

2.05633.06655.03018.084 I9.00588.0805

7.0561

8.02655.0404

4.0616

8.03619.07844,00866.03791.00931.00539,13515.00622.0501

2.0519

8.01687.05669.0798

8.03612.02319.1162

3.0227

2.03359.0379

3.07284,0005

6.06473.03895.00654,04893.05043,0504

7.0953

904789.1371

9.1371

45



Cylinder test, 96 HMX/4 Viton 9.1371Cylinder test, aluminized HE effects, setup 7.0949Cylinder test, burned gases isentrope & flow 4.0039Cylinder test, CP in Cu 7.0869Cylinder test, EA eutectic and others 7.0553Cylinder test, EA systems 8.1004Cylinder test, eutectics of ammonium nitrate 7.0801Cylinder test, ideal explosive predictions 6.0446Cylinder test, LX- 14, velocities 8.0616Cylinder test, metal acceleration 4.0003Cylinder test, NFZ performance 7.0940Cylinder test, off-center initiation 7.0755Cylinder test, RDX/TNT mixtures 6.0516Cylinder test, temperature, particle size 8.1018Cvlinder test, two-part, AWRE EOS method 7.0678Cylinder test, ZrHz-based composites 9.0525Cylindrical & spherical detonation, mixtures 9.0766Cylindrical case expansion, JWL, Gurney equation 9.0498Cylindrical converging detonation, D vs l/r 7.0602Cylindrical diverging detonations, model 7.0669Cylindricttl shock tube, converging waves 1.0081Cylindrical tube cell for gas flow model 8.0915Cylindrically symmetric hot boundary in wave 4.0083Dagmar model, correlation with shock data 8.0108Dagmar model, reflected shock, rarefaction 7.0385Damage characterization, energetic materials 9.1295Damaged energetic materials, shock sensitivity 9,1295

Ditrk-wave failure of 1,2-DP, reinitiation 5.0097Dark-wave mode of failure & reinitiation 5.0089Dark waves, detonation front 7.0958Dark waves, homogeneous HE detonation, photos 6.0414Dark waves, liquid HE, failure effects 5.0169Dark zone in shock initiation 3.0786DATB, detonation properties 3.0761DATB, detonation properties, carbon EOS 8.0528DATB, radicals in decomposition products 8.074DATB, thermal initiation and growth 5.0280Dautriche effect, detonation waves colliding 7.0757Dautriche method, D, unreproducible results I .0009Dautriche method, D for contlned TNT 3.0354Dautriche method, test setup 2.0586DBA- 1, -2, -3, densities, D, cd, P 3.0381DDNP, bum rate, sensitiveness 2.0651DDNP, deflagration before DDT 1.0059DDNP, drop-weight initiation test 3.0012DDNP, EMV particle velocity mess. in detonator 9.081DDT, conduction pulse peak to initiation 3.0156DDT. CP, summary of properties 7.0865DDT. direct observation in glass tubes 7.0873DDT, dynamic compaction of inerts 7.0843DDT, dynamic compaction, intragranular stress 8.0645

46

DDT, early work 3.0788DDT experiments, test for existing theories 1.0057DDT, gas evolution & gas escape vs pressure I.ollttDDT, gas-phase reactions 7.0216DDT, granular HMX 9.0265DDT, igniter and compaction effects 7.0143DDT in CP study 6.0455DDT in nitroglycerin, bubble effect 3.0455

DDT in PETN & RDX, free-run laser initiation 6.0612DDT in primary HEs 9.1100DDT in propellants & explosives, quantitative 3.0635DDT in propellants, risk testing 6.0299

DDT in RDX and ball powder, porous beds 8.0972DDT in solids, chemical kinetics, calculations 3.0606

DDT, laminar to convective burning 7.0164DDT model, compacted porous beds, BRL 7.0198

DDT model, granular explosives 8.0669DDT model, compacted porous beds, NWC 9,0363DDT model, cased propellant, propagating flame 7.0143DDT model, propellant, cast-granular interface 8.0962DDT model, TS 3659 propellant 9.0329DDT modeling, granular materials 9.0293DDT, numerical modeling 9.0259DDT parameter, particle diameter, largest influence 9.0320DDT, porous beds of propellant, model 8.0934DDT, porous beds 9.0259

DDT, porous beds of ball propellants 9.0341DDT, porous explosive, consumable 8.0914DDT, porous HE, high strain rate deformation 8.0881DDT, schlieren photos & plots, CO/0#-L2/etc. 2.0284DDT, simulation of compaction wa~’e 9,0306DDT stages for porous charges 8.0658DDT studies, RDX & RDX/wax, steel confinement 9.0259DDT studies, spherical ball propellant 9.0354DDT study, P@ + pyridine in steel tube 7.0151DDT study, CP characterization 7.0865DDT study, double-based propellant 8.0658DDT study, Drernht’s decomposition mechanisms 6.0029DDT study, high-HMX solid propellants 7.0256DDT study, porous HE in plastic tubes 7,0119DDT study, RDX, “resonation” wave 5.023 IDDT study, small diameters in RDX, HMX, HNS 7.0107DDT study, steel-contlned RDX/wax 7.0139DDT study, tetryl, fine & coarse, c85Y0 TMD 6.0426DDT, successive phases, gauges 9.0259DDT test data vs Krier/van Tassell gun model 6.o~5g

DDT tube setup, propellant study 8.0659DDT tube test, RDX/wax, experiments & model 90320DDT tube tests, ball powder, model 8.093SDDT tube tests, HMX, radiographs, model 9.0265

DDT, two isomeric cast primary explosives 6,0~31

.

.

.

.

I


Subject Sy.Pg Subject sY,Pcl

DDT, wall trace records for NM-acetoneDDT, wedge test run to detonation

De Laval nozzle, flow conditionsDead pressing, failure of DDT at high densityDead pressing, failure to detonate (preshock)

Dertd pressing, no bum to detonationDeal’s air-match points

Debonding & crystal fracture vs explosivenessDebrix 18AS, sensitivity and explosivenessDebrix 2, EMP velocity gaugesDebye continuum theory, shock compressionDecay of shock waves, solids & Al spallings

Decay zones near front of detonation waveDecomposition, NM, drop-weight impact

Decomposition, new HE, drop weight impactDecomposition energy, heat, radiation

Decomposition, fast transient, kineticsDecomposition front reaction

Decomposition kinetics, emission spectraDecomposition mechanisms, arbitrary

5.0105

9.0322.07549.11003.0785

2.06294.00637.0020

8.02658.04477.0523

3.02535.00189.1019

9.10373.0843

9.11407.07898.0710

9.0633Decomposition mechanisms, C-N bo_nd, NM, NH, 9.1027

IJecomposmon proctucts, emission spectraDecomposition rate vs pressure (FOREST FIRE)Decomposition reaction kinetics, lead azideDecomposition reaction kinetics, shock front.Defect microstructure in HE single crystalsDeflagrating explosives or propellantsDeflagration & detonation velocities, probeDeflagration, accident simulationsDeflagration, before detonation, photosDeflagration, CO-O, explosion, x-t plotDeflagmtion, deuterium, laser drivenDetlagration, from EBW-initiated capacitor

Deflagration, induced at ambientDeflagration model, fragment impactDeflagration, principal meani of propagation

Deflagration rate, HE + propellants, > 1 kbarDeflagration, schlieren photo, CO/0#H#120Deflagrrition, shock-induced, desensitizationDeflagration-to-shock transition (DST)Deflagration waves, unstable, heterogeneousDeflagmtions induced by direct thermal meansDeformation & HE properties of HMX powderDeformation as then-ml energy sourceDeformation heating, high aspect ratio dimpleDeformation, role in hot-spot formationDeformation, velocity distribution profilesDEGDN, radianceDEGDN, sensitiveness, m x Q

Dekazene in hydrazine, gap test sensitivity

Delay to detonation vs shock ampl., PETN, NM

.

5.U1126.0409

2.0529”7.07899.08683.07994.06168.02111.0057

2.02885.03616.02058.02167.0175

3.0433

6.01952.02869.13227.022S6.02819.13229.08868.0926

8.10807.09767.03477.0762

2.0700

3.0830

9.0235

Delayed and low detonation, model and testsDelayed detonation, card gap testsDelayed detonation, low-velocity impactDelayed-detonation transition (XDT)Demilitarization of large charges

Dense fluid EOS

Dense molecular fluids theory vs model

Density changes in gaseous detonationsDensity discontinuity, HMX/ZnC12 studyDensity discontinuity, hot-spot formationn---:... .J:-- _-.: -..:... -I-..,.1. : -.--”...:-- X11XUcmlly

DensityDensityDensityDensity

Density

DensityDensityDensity

DensityDensity

DensityDensityDensity

Density,

U1>UU1lLIUUILY , >llUUA 111LG1clGLIU1l, 1’41V1

discontinuity, shock interactioneffect, DDTeffect, DDTeffect, detonation front

effect, gap test

effect, HNS-SF sensitivityeffect, initial, scaled radiuseffect, run time and pressureeffect, stretched/unstretched HE

effect, underwater

fluctuation construction schemeof HMX/emulsion vs 0/0 HMXsnapshots, PBX 9502strongest pressure influence

Density surface contours, TATB modelDensity vs shock sensitivityDent & detonation velocity tests, 3/8-in. diam.Dent test results, azide/PETN detonators

8.0135

7.02657,02567.0258

9.13228.07858.053 I2.0187j.01875.01774.0386

4.03947.01137.01667.0768

7.0336

7.10266.0564305144.0500

6.056 I

8.06809.05459.06834.01798.00509.00986.04412.0723

Denton’s correlation for heat transfer to porous bed 90363Desensitization by preshocking HE

Desensitization by shockingDesign, precision linear shaped charges

Detasheet C, physical propertiesDetonability experiments

Detonability of carbohydrate-metal compositesDetonability of mixtures of C, BN, Si

Detonabilhy of propellants & explosivesDetonability test setup, preshocked HEDetonating diatomic lattices (MD)Detonation behavior of liquid TNTDetonation calorimeter, PETN detonation heatDetonation calorimetry, Cu cylinder testDetonation calorimetry, Spectrometer, model

Detonation calorimetry, fluorine oxidizerDetonation characteristics, gun propellantsDetonation chemistry, fluorine oxidizers

Detonation criterion, P% = const.Detonation development, thin flyer-plate impactDetonation enhanced by electric current flow

Detonation failure & shock initiation model

8.0047

3.08059,1385

8.03639.0018

9.0972

9.07663.06358,10588.0864?.04394.0167

904789095370942

9.05377.0940

6.0076

9.00669.0388

5.0177

47



DetontttionDetonationDetonationDetonation

DetontttionDetonation

DetonationDetonationDetonationDetonationDetonationDetonationDetonationDetonationDetonation

failure, NM, 2D simulationfailure, velocity-diameter theoryfront curvature, HNSfront photos: NM, NM/acetone

front, shaped charge, recordfront structure, gaseous, reaction

head model, wa~’e shapeshead shapes, spherical ignitionhead theory, reaction rate, TNTISNif burn surface v > sound speed

in gases at low pressurein high vacuumin homogeneous explosiveslight, bubbles in NM, camera record

limits in condensed explosives

7.06087.05899.02097.09587.0751

2.0216

2.05016.0525

2.05192.0695

2.025 I5.0559

2.04543.04814.0179

Detonation mechanisms, mining safety HEs 9.1351Detonation model, mtdtiprocess, Russian 9.0724Detontttion parameters, AMATEX 20 & Comp B 7.1082Detonation parameters, NlvVdiluent 6.0136Detonation parameters, one embedded foil 8.0440Detonation parameters, predicting with VLW EOS 9.0435

Detonation performance calculations, KW EOS

Deto~ation pressure, AN, Japanese-Dutch testsDetonation pressure, function of lengthDetonation pressure measurement, manganin foilDetonation pressure, NM driving dural,”decay”Detonation pressure, PBX 9404, Comp B, NM,Detonation pressure, simpler predictionDetonation pressure, x ray of wave vs time

DetonationDetonationDetonationDetonationDetonationDetonation

DetonationDetonationDetonationDetonationDetonationDetonationDetonationDetonationDetonation

DetonationDetonationDetonationDetonation

DetonationDetonation

Detonation

4s

pressures, calculationprocess in P-V plane, CJ point

product EOSproduct EOS, baratolproduct EOS, Monte Carlo methodproducts (elements) effect on HE

products below the CJ stateproducts, carbon clustersproducts EOS, EED, e-p-vproducts, ys, molecular properties

products into argon & vacuumproducts study, apparatus

propagation, PBXW-I 15properties, 95 TATB/5 Kel-F 800properties, AN emulslon, model

properties, explosive foamsproperties, KHT EOS modelproperties, NTOproperties, ZOXresearch in China, sumeyshock dynamics, 2D model, DSD

shock dynamics, deton. ivave spread

3.07259.05605.00599.04715.00187.05317.09535.00139.0461?.0345

9.05069.13789.04526.07105.05239.04179.03889.05139.09628.07029.08069.01239.06219.13648.05489.10019.09857.0795

9.07309.0773

Detonation state, series of Ta foilsDetonation structure, molecular dynamicsDetonation Symposia indexes, 1981-1985Detonation temperature, 4-color pyrometerDetonation temperature, charge-core radiation

Detonation temperature, liquid HEs

Detonation temperature, liquid & solid HEsDetonation temperature, solid HEs

Detonation temperature, theory, TNT & tetryl

Detonation threshold data, TNT-filled targetsDetonation threshold velocity, impact effect

Detonation thresholds, PBX 9404 & RX-26-AFDetonation tube, standard (French), photoDetonation velocity, ANFO, TNT, emulite, . . .Detonation velocity, calculated, CJ, EOSDetonation velocity, curvature functionDetonation velocity, curvature function

Detonation velocity, curved-liner effectDetonation velocity, density, AN, model

Detonation velocity, density, ANFODetonation velocity, density, DATB

Detonation velocity, diameter studyDetonation velocity, divergingDetonation velocity, EDC35Detonation velocity for HMX/emulsionDetonation velocity, from Hugoniot minimumDetonation velocity, linear vs densityDetonationDetonationDetonationDetonationDetonationDetonation

DetonationDetonationDetonationDetonationDetonationDetonationDetonationDetonation

DetonationDetonationDetonation

DetonationDetonationDetonationDetonationDetonationDetonationDetonation

velocity, measurement, pin methodvelocity, oscillograph trace, PETN

velocity, radius (D vs l/r)velocity, radius (D vs I/r)velocity, simpler predictionvelocity, sphere, cylinder, planevelocity, vs initial densityvelocity, vs charge density

5.00059.07139.15438.05582.0157

7.0759

9.0939

9.09472.01657.10517.02737,0325

6.01268.09871.01077.06029.07846.0523

9.0560

3.03143.0764

2.0133

8.01519.08229.05452.0387

2.04162.01361.0013

2.04803.03117.0953

5.00412.03905,0074

velocity vs particle size, composite HEs 9.0554velocity vs p, 60 PETFU40 PU foam 9,1364velotiity vs p, emulsion HEs 9.0573velocity vs p, NM foam 91364velocity, wall effect on EDC35 9.0831wave, decomposition of HE 9.0050wave, fronts, interacting with inerts 1.0093wave, fronts, ideal/nonideal 2.0500wave, fronts, subsonic, container veloc. 5.00S5

wave, fronts, interactions, modeling 5.0487wave, fronts, generators, families, types 5.0517wave, fronts, interactions, modeling 7.0669wave, fronts, theory, Chinese 7.0795wave propagation from impact region 9,0798wave spread, deton. shock dynamics 9.0773

zone, condensed explosives 2.035S

.

.



Detonation zone, peak luminosity measurement

Detonator design & fabricationDetonator, non-steady flow

Detonator response measurem. with PVDF gaugeDetonator stresses, momentum, time, distance

Detonators, M29 & M47, development

DETOVA code for DDTDETOVA model, DDT, dynamic compactionDeuterium shocked by pulsing Nd laserDFB, failure diameter, timesDFB, liquid HE, characterizationDFF, liquid HE, characterizationDFNT, liquid HE, characterizationDiameter effect, CJ parameters, KHT EOS

Diameter effect, condensed explosivesDiameter effect, detonation velocity, 2ND

Diameter effect, detonation velocitiesDiameter effect, detonation velocity

Diameter effect, diverging detonation wavesDiameter effect, eyring theory, limits

Diameter effect, high-density heterogeneous HEDiameter effect in liquid NO

. Diameter effect, liquid TNT, dural & PyrexDiameter effect, NM, Jones & Eyring theoriesDiameter effect, NM-PMMA-GMB

.Diameter effect, non-ideal explosivesDiameter effect, nonideal detonations modelDiameter effect, on wave shape, ideal HEDiameter effect, on DDTDiameter effect, PBX 9404, Comp B, PBX 9502Diameter effect, reaction zone thickness

Diameter effect, slun-yDiameter effect, TATB/HMX mixtures

Diameter effect, theories, early workDiameter effect, theory & experimentDiameter effect, varioui theories compared

Diamond in detonation products

Diamond-anvil cell, NM decompositionDiamonds, graphite & volatiles in detonation sootDiamonds, synthesis in detonation wavesDichloro-TNT, radicals, decomposition productsDielectric liquid explosives, transducersDielectrics (liquid) in shock wavesDifference equations, 1D flow, isentrope + EDiffusion-controlled reaction rate modelDiffusion effect in comptisite explosives

Diffusion layer calculationDiffusion method for growing Iead azide

Diffusion role in detonation chemistryDiffusion-controlled reactions of HEsDiluent effect on methyl nitrate sensitivity

.

1.0039

2.0720

9.0816

9.15293.0285

2.07129.03297.0850

5.03615.0089

6.04676.04676.04678.0996

2.04241.0105

2.0202

3.07918.1046

4.01806.06429.13352.04492;04549.0925

9.01977.0699

2.05057.01107.05334.0096

8.01687.0567

3.08018.0168

2.0482

9.04179.10199.11709.0407g.07424.06095.03993.06087.0520

4.0193

8.10127.07369.11939.07435.0271

Diluent effect on propagation of NMDimensionless explosive/jet parameter

Dimple tests, three variations, Comp B

DINA, BKW model & performance data

DINA, confined effects, failure diameter

DINA, electrical transducer studiesDINA, NM, TNT, dithekite shock initiation

DINA, time delay vs temp reciprocal, decomp.DINGU, performanceDINGU, sensitivity and performanceD~GU, synthesisDINGU, vs TATB, comparison of propertiesDIP mass spectrum from TNT sootDirect-contact detonation sensitivity testDiscontinuities in HE-driven plate tests

Discontinuities in models, Q & LAX methods

Discontinuity angle of shock waveDiscontinuous diameter-effect curves

Discrepancies in EOS, add formic acid

Disk standoff distance effect, velocityDislocation dynamics, cracks in elastic mediaDislocations, RDX, PETN

6,0133

g.lo918.1080

3.072f3

3.0800

4.06093.04693.0068904788.03518.0351 I

7.05409.11704.0404

4.0645

3.0615

4.0258

9.0197

8.0S407.03066,02689 1~76

Dispersal, explosive, heated Al particles into water 9.0641Displacement gradient method, flash x ray 8.0440Disposal of surplus ammunition 9.1322Dissociation energy vs detonation velocity, N2 2.0244Distance-time plot, buildup to detonation 5.0248 IDistance-to-detonation tests 7.0888Distance-vs-pressure plots, PETN, 2 densities 6.0371

Distance-time plot of double impact of piston 9.0306Dithekite, DINA, TNT, NM shock initiation 3.0469

Dithekite, plasma, streak camera 3,0200 “Dithekite, sensitiveness, Q, m 2.0648Divergence, IHE 9,U123Divergence testing, EDC35 9.0123Divergent detonation waves, Whitham’s theory 9.0784

Divergent spherical detonation waves, solid HE 5.0031Divergent’ spherical generator, calibration 91371Divergent wave, flow derivatives, heat 8.0148Diverging & converging detonation experiments 9.1217Diverging detonation, computation, Comp B 9.0743Diverging detonation, computation, Comp B 9.0751Diverging detonation, mushroom-shaped sample 9.1217 IDiverging detonations, RDX & PETN~based PBX 70408

Diverging shock wave in Plexiglas cylinders 5.0477Diverging shock wave initiation, RDX/TNT 8.01-13DNBF, shock sensitivity 9,0561

DNBF, shock sensitivity, phys. & them. properties 9.0566DNNC, time to explosion 9.0228

DNP, detonation properties 6.0100

DNP, sensitivity, cavitation effect 7,0373

* ‘/9 I



DNP, thermal decomposition at P= 10-50 kbarDNPP, liquid HE, characterizationDNPTB, impact sensitivity, critical temp

DNT, diameter effect, D vs l/d, limit dataDNT, radicals in decomposition products

DNT, sensitivity, cavitation effect

DNT, threshold velocity, bum rateDoering-Kirkwood-Wood, increase in velocityDonor charges initiating acceptor chargesDoppler laser interferometry, velocity studyDoppler shift velocity interferometer, recordDouble-base propellant, gap test sensitivity

Double-base propellant, casting solventsDouble-base propellant, DDT study

Double-cartridge test, sensitit’eness

Double-pipe test (DPT), ANFO in 40-mm diamDouble-wedge test, TATB and HMXDouble-base propellants, pressure shear ignitionDouble-bttsed ball powder, DDTDoubly shocked HMX, smear camera recordDownstream Mach number plots

DP (1-2 DP), exper. & talc. CJ parametersDRE~ gap test, shock sensitivityDREV setback simulatorDrop hammer, IHE test, laboratory scaleDrop weight apparatus, explosiveness, skidDrop weight impact test, colliding ballDrop weight impact test, polymer effectsDrop weight impact test, TATB/HMX

Drop weight impact test, hot spots, shearDrop weight impact, HMX & PBX deformationDrop weight impact, mechanical properties

Drop weight impact, transparent anvilsDrop weight impact, radiometry & spectroscopyDrop-weight impact, HE decompositionDrop weight impact, HE decompositionDrop-weight impact, shear bands role in initiationDrop-weight-impact tests, fluctuating response

DSC, emulsion HEsDSD, examples for detonation wave spread

5.0331

6.04673.00694.0182

8.07427.0373

6.01192.01982.0621

8.08156.06733.08304.04218.0658

2.0604

8.03908.08929.00039.02593.05115.0131

6.0713

8.03619.14807.0965

6.02913.00017.00247.05707.09709.08868.0635

8.06359.10379.10199.10379.1276

9.12439.05859.0773

DTA for BTX, new high-temp EBW explosive 6.0460Duitl-delay-leg velocity interferometer (VISAR) 6.0668Dual velocities of detonation: NG, TNT, tetryl 2.0583Dust particles interacting with airblast 6.0784DXD-O 1, detonation pressure profile 9.0471DYNA2D, 2D Lagrange code, porous bed analysis 9.0280DYNA2D, explicit hot-spot model 8.0058DYNA2D model, failure radii & comer turning 7.0488DYNA2D, reactive flow analysis 9.1224Dynamic compaction, porous beds of inerts 7.0843Dynamic compr, properties, HMX compounds 8.1037

5(J

Dynamic compressive strength effects

Dynamic detection, spalling, stainless, Comp BDynamic impact model, 2D LagrangianDynamic radiographs, spherical detonation

Dynamic stability boundaries, deflagration

Dynamic stress-strain data, camera recordDynamite, calculated blasting performance

Dynamite, explosive performance characterizedDynamite, lateral shock pressure tests

Dynamite, thermal hazardEA, eutectic of EDD and AN, performance testsEAK and EAKL, intermolecular explosives

EAK, eutectic, non-steady-state effectsEAK, gap test results

EAK, Lagrange gauge study of initiationEAK, low explosivity but not low sensitivityEAR (EDD/AN/RDX) plate dent test dataEarly-motion test, AWRE cylinder testEBW, cause of energy limitEBW detonator, high temp, new explosive (BTX)

EBW, illumination in I*C photos, PBX 9404Ector electron-beam HE detonation

EDC29 & EDC32, wave shapes in rodsEDC35 IHE, frozen hot spots in shocked

EDC35, inert wall effect, detonation velocityEDC35, initiation & detonationEDC35, wall effect on detonation velocityEDD, eutecticsEDD performanceEdge-effect steady-state detonationEDNA, impact sensitivity and OB/100EDNA, limit data, high reaction zone

EDNA, sensitivity and oxygen balance dataEDNA, time to explosion

EDNA, wave curvature vs charge lengthEDNP, liquid HE, characterizationEE, emulsion explosives, talc; of det. properties

EED, electrically enhanced detonation modelEfficiency, HE, theoretical predictionEfficient temperature,> shock pressure of EOS

EGD, sensitiveness, m x QEGD, sensitiveness, Q, m

EGDN, bubble energy, underwater expansionEGDN, light emission during initiationEIE, French ion-exchanged explosiveEinstein vibrational frequency, partition FELA 2D model, AWRE EOS determination

ELA 2D steady-state codeElastic half-space, water surface detonationElastic modulus, PETN crystals

Elastic modulus vs strain rate, Octorane 86A

7.0017

6.0477

6.0336

5.00366.0281

3.04208.09876.07294.00957,00437.05488.01118.10018.0232

9.00898.10057.05517.0680

4.04496.04606.0666

9.11319,07849.12539.082?9,01239.08317.05489.04786,03563.06744.0184

3.06999.02282.05066.04679.0621

9.03889.04896.0105

2.07002.06496.05465.01534.0156

2.04077.06784,0014

5.04976.0400

9’1047

.



Elastic precursor decay model, with cracksElastic precursor waves in Fe and quartzElastic precursor waves in LVD, cavitationElastic precursor waves in shocked Be

Elastic-plastic flow in aluminaElastoplastic effects, attenuating shock wave

Elastoplastic release of Mg at 80 kbarElectric boundary values, Laplace’s equationElectric field initiation, explosive azidesElectric gun experiments. particle size effects

Electric gun, initiating TATB, short shockElectric gun, initiation studies

Electric gun test setupElectric probe technique, detonation & defkig.

Electrical conductivity, detonating condensed HEElectrical conductivity, detonation productsElectrical conductivity, liquid dielectricsElectrical effects in pin method, velocityElectrical initiation of RDXElectrical junction effect, shocked metalsElectrical resistance of ionized zone

Electrically accelerated flyer plate system. Electrically driven thin flyer plates

Electrically enhanced detonationElectrochemical electrode effect, lab stockElectrode interface effects, lead azideElectromagnetic gauges, NM SDTElectromagnetic velocity gauge, radial flowElectron beam heating, stress pulse measuredElectron beam initiationElectron bombardment decomposition, azides

Electron density distribution analysis, NQElectron micrograph, shocked HMXElectron paramagnetic resonance (EPR)

Electron paramagnetic resonance spectraElectron beam initiation of TATB HEsElectronic excited states, bond scissionElectrostatic potential map, NQElectrostatic sensitivity testing of HEsEmbedded foils, detonation state measuresEmbedded foils, x-ray photos, fits toEmbedded gauge measurements vs RFLAEmbedded gauges, LX- 17

6.0267

4.05695.0085

.5.04679.0842

4.02774.02904.05966.03909.0025

8.03809.0066

8.11264.0616

9.03964.0595

5.03992.01413.00886.0151

3.01126.0653

9.00669.0388

5.03996.03939.00399.00775.03517.00502.0531

8.08399.08978.0734

8.07429.11317.0093

8.08459.10765.0004

5.00167.04668.1053

Embedded gauges, LX-1 7 initiation vs temperature 9.0112Embedded gauges, mangami~, TATB initiation 7.0385EMF static & dynamic loading, C.T. E./Cu junction 4.0633Emission intensity, reactivity indicator 8.0015Emission spectra, detonating HNS 8.0694Emission spectra, Hg(CNO), & C,H(N02)3(0,Pb) 8.0710

Emission spectroscopy, drop weight impact on HE 9.1019EMP gauges, steady-state velocities 8.0187

Emulite, air Hugoniot & isentropes, modelEmulite, calculated blasting performanceEmulite, precursor air shock in air gap

Emulsion explosives, mixtures with HMXEmulsion explosives, performance tests, model

Emulsion HE, diameter effectEmulsion HEs, detonation properties, calculatedEmulsion HEs, performance vs diam & density

Emulsion HEs, shock sensitivity

81077$30987

8.1072

9.0545

8.0985

9.0197

9.06219.05739.0585

Emulsion HEs, underwater explosion 9.0641Emulsions, glass microballoons, performance 8.0993EMV gauge, assemblies, (electromagnetic velocltv) 8.(J 102EMV gauge, Hugoniots, porous TNTEMV gauge, rise time, flow perturbationEMV gauge, schematic, particle velocities

EMV gauge, technique, PMMAEMV particle-velocity gaugeEN, bum rate, sensitivenessEN, radiance & detonation tempsEN, sensitiveness

EN, sensitiveness, Q, mEN, shock compression through inert, DDT

EnergyEnergy

EnergyEnergyEnergyEnergyEnergyEnergyEnergy

EnergyEnergy

Energy

EnergyEnergyEnergy

EnergyEnergy

band diagram, Scottky-barrier contactdelay effect on blast wave

effect on decomposition of DDTfractions, bubble, heat, mechanical,.,.localization, predicting hazard responseloss, multipoint initiationoutput of HEs, parametersrelease, chemical systemsrelease, rate model, flow fields

threshold vs shock pressurethresholds for direct laser initiationto ignition, impact ignition & growth

transfer efficiency, plates & cylinderstransfer, phenomenological modelstransfer to rigid piston after impact

kansfer vs mass ratio, spheres, modelslevel diagram

Energy-per-unit-area criterion, impact on HEEnhanced thermal diffusivity, shocked PBX 9404Environmental shock testing, condensed phasesEOS & criticality conditions for liquid HEEOS, 1060 aluminum, shock wave measurementEOS, aluminumEOS, aluminumEOS, AN-based HEEOS, antimony

EOS, argon, expansion isentropes of TATBEOS, baratol detonation product

EOS, based on intermolecular potentials

607667.10625.04135,04139.08162.06517.0762

2.06992.0648

3.08136.0391

7.07293.(J8426.05549.12439.13609.09623.07387.049s

6.01129.11189 l~q~

4002190713

3,02056.05269.0235

9.14417.10063.00244.0395

4.0213?.03543,0358 -8,099760602

8.0s169.13787,0703

.51



EOS, C and NEOS, calibration method

EOS, carbonEOS, cast PBX @MX/polyurethane)

EOS, CHNO explosives properties modelEOS, CJ conditions (K-W)

EOS clusters, CHEQ codeEOS, Comp BEOS, comparison of various HEsEOS determination, AWRE methodEOS, detonation gasesEOS, detonation parameters, Chinese

EOS, detonation products, gasesEOS, detonation products, Comp BEOS, detonation products, at P <30 kbar

EOS, detonation products, C vs HCOOHEOS, detonation products, introduction

EOS, detonation products, VLW EOSEOS, detonation products, Monte Carlo methodEOS, detonation temperatureEOS, elastoplastic materials, Al, Cu, C-7EOS, Fickett & WoodEOSWfluid perturbation, talc. detonation pressureEOS for detonation productsEOS, gas & liquid, Lennard-Jones-DevonshireEOS, granular HE, pulsed electron beam

EOS, graphite at TNT CJ pointEOS, HZ-O: detonations

EOS, HBX-1EOS, HE, model

EOS, HMX/polyurethaneEOS, HMX/TNTEOS, HNAB, rate modelingEOS, JCZ, TIGER codeEOS, JCZ3EOS, JWLEOS, JWLEOS, JWL

EOS, JWLEOS, JWLEOS, JWL


EOS, JWLEOS, JWL


EOS. JWL

EOS, JWL parameters using Gurney equation

9.0425

8.0794

8.05218.05997.07034.0027

9.07434.0003

9.06217.0678

1.00727.0795

4.00294.00474.0052

8.05408.0785

8.07969.04529.09394.02804.00529.04619.03881.01085.0351

2.04012.0221

5.0531

9.04437.06784.00247.04166.01639.09335.00087.0488

7.0678

8.0596

8.09098.09148.0947

9.00259.01339.01429.02099.0498

9.06709.07019.1217

9.0498

EOS, KW

EOS, KWEOS, KWEOS, KNBEOS, KHTEOS, KHT

EOS, KHTEOS, KHTEOS, LuciteEOS, LX-14

EOS, Mie-G~neisenEOS, Mie-Grtineisen

EOS, Mie-Gri.ineisenEOS, Mie-GrtineisenEOS, Mie-Griineisen

EOS, Mie-GrtineisenEOS, Mie-Griheisen

EOS, Mie-GfineisenEOS, nitromethaneEOS, NTOEOS of dense gaseous HEs

EOS of detonation productsEOS of detonation products, TATBEOS, PANDA codeEOS, PatersonEOS, PBX 9404EOS, Percus-Yevick

EOS, Percus-Yevick

EOS, PETN detonation productsEOS, Plexiglas

EOS, PMMAEOS, polytropic, CJ parameters vs areaEOS, porous material (insulboard)EOS, RDXEOS, reactive mixtures, postdetonationEOS, solid explosive (Tait) + isentropeEOS. TATB, virial, detonation productsEOS, TIGER/BICWR, eutectics of EDD & AN

EOS, TNT, bum model from LSZK EOS

EOS, TNT, impacted, unconfinedEOS, TNT/NaN03 50/50EOS, unreacted explosive

EOS, uranium after shock loadingEOS, VLW, CJ calculations for CHNO HEsEOS, VLW, comparison with BKW and LJDEOS, VLW, predicting detonation parametersEOS, waterEOS, waterEOS, water, twin sphere interaction

EOS, WCA4

EPR, high-acceleration chemical reaction

2.0383

3.07254.00272.0520

4.01738.0548S.07648.09973.05849.04254.0205

5.00675.01965.03525.05547.0362

9.00509.03297.06099.04899.0933

9.03889.05069.04433.07227.04078.0764

9.09335.0503

5.0477

5.04777.05893.03967.07167.0650

3.06109.05067.0555

5.04905.03162.0519

3.05425.05478.0796

8.07969.0435

3.03574.00275.0581

805218.0~43

.

.

.

.

.

.



EPR, products from condensed phase HEsEPR, radical identification

EPR resonance, trinitroaromatics

EPR spectra of tetryl, TNT, DNT, and DATB

EPR theory, decomposition of RDX & HMXEPR, thermal decomposition of nitraminesEquation of motion, curvature effectsEquilibrium in C2N40#Jz, proof of CJ theory

Equivalence of EED & unsupported detonationEremenko’s relative detonation impulses

Erythrosin in azide photochemical initiationESD test, electrostatic discharge, common HEsET, e[hyldecaborane in tetranitromethane, Pc,, DETARC, a thermochemical codeETARC code, chemical equilibrium model

Ethylene/air detonation velocity vs initial pressureEulerian, Lagrangian coordinates coupled, modelEutectic, AN-based HEEutectic, AN-composite explosivesEutectic, AN, cosolidification, indicesEutectic, m.p. of binary mixtures, liquid HE

Evans’ limits in homogeneous explosi~’es. Excess transit time vs flyer velocity

Excess transit time, thin flyer-plate impact

Excimer laser initiation, spectrography.Excitation and dissociation, molecular collisionExpanded large-scale gap test (ELSGT)Expansion isentropes, TATB compositionsExpansion wave behind detonation front, impactExploding-foil shock sensitivity testExploding-wire detonator, PETN surrounding itEsploslve deflection of a linerExplosive-driven HE, shock waves in x rays

Explosive-driven metal, modelsExplosive-filled transducer, charge assembly

Explosive foams, detonation properties

Explosive grains, Comp B, TNT, M30A1Explosive parameters, conical shaped chargesExplosive-plate interface, velocity, Comp B/SSExplosive properties, effect of SFj groupExpIosive reaction zone, calibration for modelsExplosive shock adiabat, compressibilityExplosive wedge test, setup & streak recordExplosiveness, test for shear ignitionExplosiveness, AWRE labset testExplosiveness in setback simulator testsExplosiveness, munition fillings

Explosiveness of large charges

Explosiveness, RARDE burning tube, confined HE

Explosiveness, response, HhlX-based PBXS

Explosiveness, small-scale skid test

9.0939

8.0734

8.07428.0742

8.07347.0075

1.00952.0238

9.03887.0952

2.05549.1076

3.07449.04897.07059.0933

4.05298.09977.0801

6.04486.0470

4.0190

6.0660

9.0798

8.07109.10849,12848.08154.05607,0924

1.00095.04574.0646

8.06024.0611

9.13647.0899

8.10934.05459.11629.02527.07916.00229.00037.00179.14807.1040

9.13227.1040

8.1035

6.0290

Explosiveness, VS minimum impact velocity 8.0268Explosophorous bonds, sensitivity, C-NOz 7.0066EXTEX, minimum priming charge test model 7.0479Extrudable HE, 36 new liquid carriers 6.0466Eyring’s curved-front theory 3.0310Eyring’s cylinder detonation, diameter effect 3,0787Eyring’s equation for uncofllned charges 2.0461Eyring’s theory & technique discounted 2.0452Fabry-Perot interferometer, schematic 8.0124Fabry-Perot interferometer, free-surface velocity 8.0596Fabry-Perot interferometry, applied to detonics 9.1371

Fabry-Perot laser interferometry, ZrHz composites 9.0525Fabry-Perot velocimetry, lD, PBX 9502 9.0657Fabry-Perot vs rotating-mirror results 8.0617Fabry-Perot interferometry, electron beam initiation 9.1131

Fabry-Perot velocimeter, baratol deton. productsFabry-Perot velocimetxy, LX-17Failure & reignition processes, NM/PWAl

Failure cone and failure wedge setupsFailure diameter, bis-difluoroamino alkanesFailure diameter, calculating

Failure diameter, charge setupFailure diameter, emulsion or composite HEs

Failure diameter, for PBAA propellants (RDX)

Failure diameter, gun propellantsFailure diameter, nitric oxide, shot setupFailure diameter, RDX additionFailure diameter, solid composite propellantFailure diameter test assemblyFailure diameter theory, Dremin f(TO)Failure effects, dark waves in liquid HE

Failure limit curves, TNT, diam vs densityFailure mechanisms, mining safety HEs

Failure radii, data & model, hot spots

Failure radii, tests, PBX 9404 & LX-17

Failure thickness modeling, PBX 9407Failure waves, photo mapping techniqueFailure-diameter test assemblyFalling-hammer test, MN sensitivityFast-burning reaction, PETN, framing cameraFast decomposition of HE, initiationFCT, flux-corrected transport methodFDA, liquid HE, characterizationFDEE, liquid HE, characterizationFDEK (AN/ADNT/EDD/KN) sensitivityFDNE-A,-N,-S, liquid HE, characterizationFDNEP, liquid HE, characterization

FEFO, experimental & calculated CJ parameters

FEFO, liquid HE, characterization

Fiber optic detectors used with streak camera

Fiber optics assembly, shaped-charge test

9.1378

9.01336.0130

8.09805.00899.1351

5.00919.0573

4.0105

9.05376.07244.00974.01029.0708

5.00995.01695.0211

9.1351

6.04117.0488

9.12245.01159.0701

5.0?683.00169.08579.03206.04676.04677.08046.04676.0467

6.0713

6.0467

8.0381

8.0462

53



Fiber optics, cased device, m-rival timeFiclcett & Wood EOS, straight-line CJ adiabat

Fickett-Jacobs cycleFinite-difference mesh, 2 charges underwaterFinite-difference method, flow to pistonFinite-difference scheme in Lagrangian coord.

Fi[s to P-u points for HMX/TNTFitting form design, isentrope

Fivonite, wax-gap testFlrtme analysis, tetryl, PETN, nitroglycerinFlame as reactive discontinuityFlame front position in DDTFlame height predictions, HMX in DDT

Flame propagation, convective bum modelFlame spread through propellant, DDTFlame trajectory, calculatedFlash gtrp technique, detonation pressureFlash x ray, PHERMEX

Flash x ray, instrumented shotgun, DEF, XDT

Flash x ray, Comp B, jet initiationFlash x ray, cineradiography, high speedFlat plate test, electric gun initiation

FLO, pressure-based, reactive flow 2D modelFlow behind reaction zone, plate dent resultsFlow boundary & shock wave in air, photoFlow field measurements, explosive structureFlow fields, calculation, RFLA techniqueFlow gauges, constitutive relationshipsFlow velocity, EMV & velocimeter

Flow-resistance law of Jones & KrierFluid EOS parameters

Fluld model, lD, compressible, reactive flowFluld perturbation EOS, talc. detonation pressureFluorine as oxidizer in explosivesFluorodinitromethyl compounds, sensitivityFluoromethyl- synthesis, historyFluoronitroaliphatic sensitivity, oxygen balanceFlyer acceleration, exploding metal foilsFlyer plate, collision, PHERMEX radiograph

Flyer phtte, convergent flow driverFlyer plate, critical surface area conceptFlyer plate, energy vs reaction responseFlyer plate experiments, smallFlyer plate, exploding foil, sensitivity testFlyer plate, impact test, HE sensitivityFlyer plate impact, thinFlyer plate, impact simulationFlyer plate, limiting velocity

Flyer plate, metal-HE-metal accelerationFlyer plate, oblique impact

Fl~ er plate, schematic, HNS sensitivity test

54

8.04604.0052

8.07946.05843.02054.05284.0061

8.0792

1.0023

2.05727.0225

9.03207.0169

7.01867.01437.0227

5.0013

4.06397.0299

7,0358

7.09868.06147.0328

2.07495.04615.00337.04665.04277.1064

9.03299.0461

2.03139.0461

7.09407.00847.00847.00876.06534.0645

7.08267.0316

6.00079.00667.09246.01059.07988.00527.0798

7.08114.03817.1025

Flyer plate, shock focusing 6.0062Flyer plate, slappers, air & gas effects 7.0930Flyer plate, test setup, ISL (France) 8,0362Flyer velocity calibration curves 6.0658Flyer velocity vs burst current density 8.1127Flyers driven by multipoint-initiated HE 9,1360Flying-foil tests in methane & vacuum, PBX 9404 4.0376Flying-plate explosive components, SIP gage

Foam HEs, detonability limitsFoamed HE, detonation characteristicsFoamed PETN charge, low-density HE systemsFoams, shocked, heated, pressure wavesFoil acceleration, LX- 17

Foil-motion method, CJ conditions, low densityFoils, confinement, reducing failure diameterForest Fire, PBH-9DFOREST FIRE bum model vs test data

FOREST FIRE model, target gauge records

Formic acid, EOS parameters

Four-shock configuration, oblique, reflectedFractal dimension vs spectral slopeFracture, cause for initiation

Fracture in HE-metal system, scabbing/spallingFracture, initiation of fast decompositionFracture patterns, impacts at differing anglesFracture phenomena, from sudden releaseFracture phenomena, high accelerationFracture phenomena, XPS (spectroscopy)

Fracture strength, PBXS

Fracture surface topography of HEs

Fracture zone limits vs angle of incidenceFragment attack test, sensitivenessFragment impact effects, plate & plugFraming camera, Comp B & dithekite plasmaFraming camera, record, NM/PMMA/Al, wavesFrank-Kamenetski equation, thermal explosionFree radical shock initiation modelFree radicals, Hh4.X decompositionFree radicals, RDX decompositionFree-surface motion, prediction & dataFree-surface motion, streak camera readingsFree-surface rotation, oblique shockFree-surface velocity, = 2(particle velocity)Free-surface velocity, vs plate thicknessFree-surface velocity, vs plate thickness, pinsFree-surface velocity, flat topFree-surface velocity, vs plate thicknessFree-surface velocity, vs (plate thickness/cd)lnFree-surface velocity, vs time, PBX 9404

Free-surface velocity, iron impacted, 25 GPaFree-volume increase, slower reaction, lower P

9.0822

9.13645.00476.0183

4.02669.01336.01852.04749.01427.0479

6.0027

9.04436.0572

9.09189.0842

1.00339.08575,05751.00358.02438.0243

9.0886

9.0918

5.05782.06967.1048

3.01896.01299.00037.0778

8.07378.07374.02954.05734.05661.00912.03302.03492.03814.05475,0020

5.03?46.067??.0629

.

.

.

.

.

.



Free-volume theory, fluids, Lennard-Jones-...Free-expansion, HE products, them. & hydrodyn.Free-radical in HE by paramagnetic resonanceFree-radicaI products, EPRFree-radical products in HE, a reviewFriction initiation apparatus

Friction, initiation of fast decompositionFriction sensitivity, shear ignition study

Friction test, sensitiveness testing

Front & mass velocity in evacuated chambersFront-tracking method in RCM code

Frozen hot spots, shocked EDC35 IHEFT - 1 composite propellant, shock loading

FT-2 composite propellant, shock loadingFTE, liquid HE, characterizationFTIR spectroscopy, thermal explosions

Full-motion test, AWRE cylinder testFull-surface multipoint initiation, baratolFume chemistry, diffusion & reaction modelFundamental research on explosives, NOFuze designs & technologyGamma & CJ pressure (talc) vs dural data

. Gamma law, (P-V behavior), Comp B

Gamma law, calculations, HE parametersGamma law, EOS, P-uP isentrope from CJ stateGamma law, EOS vs data, CJ pressureGamma law HE, detonation parameter relations

Gamma law EOS of PBH-9D

1.01079.0953

9.09879.0939

9.09875.02919.0857

9.0003

3.06604.01769.0751

9.12539.0879

9.08796.04679.0228

7.06799.13609.1193

8.04222.07203.0394

4.00088.09463.0387

5.00083.07549.0142

Gammas, Grttneisen & adiab., errors, molec. props. 9.0513

Gammas. Gfineisen and adiabatic 8.0791Gap test,Gap test,Gap test,Gap test,Gap test,Gap test,Gap test,

Gap test,

Gap test,Gap test,Gap test,Gap test,Gap test,Gap test,Gap test,Gap test,

8-in. -diam confined, instrumentedcard, propellants, confinementcavitation effect on sensitivitycritical failure diametercritical shock initiationcylindrical

data vs fragment impact data

ERDE, sensitivenesshistorical workIHE

initiation threshold, TNTinterstitial gas effectsliquid monopropellantslow-order reactions in shocked HElow-amp shock initiation (LASI)model vs LANL & NOL results

8.02283.08237.03733.08007.02784.04628.1151

2.0646

3.07859.01236.00365.02473.04364.04627.02857.0479

Gap test modeling 9.1451Gap test, modified, underwater shock to bum 4.0488Gap test, modified, low-velocity detonation 7.0575Gap test, modified 8.1131Gap test, more reliable for monopropellants 2.0695

Gap test, NM, 50’%0gap > with Al confinementGap test, NOL, shock pressure to initiation

Gap test, perpendicular, low-order reactionsGap test, schematic cross sectionGap test, sensitiveness, constant primer

Gap test, sensitiveness testingGap test, sensitivity, liquid HE systems

Gap test, setup, vacuum vs air

“Gap test, setup, TATB and HMX compoundsGap test, shock wave sensitivity in liquidsGap test, shocked H-6 & PBXW-109Gap test, small-scale test setupGap test, TATB formulations, Pantex

Gap test, wax, sensitivity, pressed/cast

Gap test, wax as inert barrierGap test, wax effects on sensitivity

Gap tests, shock sensitivityGap tests, small & large scaleGap thickness, compressive heating ignition

Gas bubble, screening effect, delayed arrivalGas detonation, structure & instabilityGas-dynamical model, RDWITJT initiationGas effects on flyer initiationGas evolution and gas escape vs pressure

Gas fractions, pyrolysis & final gas fractionGas gun, Hugoniot, lead azideGas gun,tests, planar sustained shocks

Gas imperfection factor f defined, K-W EOSGas in supersonic nozzle flow, shock-likeGas nonideality in CJ state, Schmidt equationGas passing through shock front into reactionGas-phase reactions in DDTGas pockets in low-velocity detonation

Gas shock velocities, HMX/TNT/inertGas-gun SDT experimentsGas-phase chemistry on hot-spot formationGas-phase conservation equations

Gas-phase influence on laser ignitionGas-phase reactions in ignition zone

Gasdynamic flow functions, dimensionlessGaseous detonation, photos, 01-H2, OZ-COGaseous detonation, rapid density changesGaseous detonation waves, air cycle talcGaseous flow from metal tube (2D), codeGaseous HEs, dense, detonation characteristicsGauge calibration, pressure, carbon resistorGauge, electromagnetic veloci~ techniqueGauge, EM, reaction rates fromGauge, EM, reaction ratesGauge, embedded vs VISAR in reactive flowGauge, EMP, intermolecular HE reaction

3.07983.0584

4.0463

5.02202.06023.06604,0412

7.0005

8.08977.0575

7.0308

5.02617.0430

1.00223.07874.04019.1284

9.05667.00036.05874.00678.01967.0931

1.0110

8.09386.03897.0385

2.03852.02952.02041.00437.02162.05824.00579.00399.0906

9.0363

9.0162

9.1151

6.05922.02812.01872.02663.02269.09335.00545,0413

8.00838.00998.09558.01S7

B. Topic Phrase Index (Continued) .

Subject Sy.Pg Subject sy.Pg .

Gauge, ionization & piezoelectricGauge, manganin, low resistanceGauge, manganin, multiply embedded

Gauge, manganin, strain compensatedGauge, manganin wire, pressure measurementGauge, multiple Lagrange, TNTGauge, multiple, studies in situ

Gauge, particle velocity, newGauge, PBX 9501 ejectsGauge, pressure, carbon resistorGauge, pressure, carbon resistorGauge, quartz, study, upstream of shocked HE

Gauge, quartz, technique for impact tests

Gauge, quartz, thick, PMMA

Gauge records, perfect vs modelGauge rise time & particle velocity (EMV)Gauss quadrature points

Gaussian 86 code, potential energy calculationsGAUSSIAN82 computer programGBFO, liquid HE, characterizationGe and Bi, complex shock wavesGelignite, shock parameters, mining explosiveGE~dinitro compounds, impact tests, OB/100Geochemical detonation in supercooled magmaGibbs free-energy, equilibrium compositionGibbsian EOSGittings’ flying foil results, vacuum/methaneGliIss microballoons, emulsion explosivesGlass mousetrap plane-wave generator

Glass transition point of Kel-F-800

2.02017.03866.00216.03306.06256.0786

7.10628.04477.0883

5.0047

9.05375.0435

5.03694.0222

7.04727.10649.0293

9.10279.11856.04675.04084.0559

3.06769.11994.01689.05138.10618.09938.0447

9.0123Global method, calibration of constitutive relations 9.0252Glucose/NG, TIGER calculations 9.0972Glycol dinitrrite, diluent effects in NM 7.0583GMB, concentration effect on NM-PMMA deton. 9.0925Grain burning, buildup to detonation 6.0011Grain-burning model, reaction zone model 3.0310Gram fracture 9.0280Grain morphology, effect on HE behavior 9.1271Grain size and combustion 9.1271Grain-burning modes 9.0280Gritin-buming process 9.0050Granular beds, HMX, DDT 9.0265Granular decomposition, Iaminar grain burning 7.0394Granular HE detonations model 8.0035Granular HE, pressed, shock to initiation 3.0562Granular material, simulation of compaction wave 9.0306Granular materials, compressive combustion 9.0293Granulometry effect on Mach reflection 8.0437Graphite, diamonds & volatiles in detonation soot 9.1170

Graphite EOS effect on D vs initial density 2.0392Graphite, polymorphic transformation, detonation 9,0766

56

Grit effect on frictional initiationGrowth of detonation from initiating shockGrowth of reaction in small charges, testsGrowth to detonation in acceptor, high orderGrowth to detonation, C-4 & AP, interferometryGfieneisen r, sensitivity to molecular propertiesGrtineisen coefficient for granular explosivesGfineisen EOS, coefficients, Cu and AlGrttneisen EOS for inert materials

Griineisen EOS, unreacted porous TNTGrtineisen r along CJ adiabat, HNBGrrheisen parameter, evaluation, metals

Grttneisen parameter, measurement, HNS 11

Griineisen parameter, precompression effects

Gun launch, simulated, defects in shell fillingsGun propellants, detonation characteristicsGurit charge, precursor air shock, detonation front

Gurney constant, simpler predictionGurney curve vs calculated efficienciesGurney energy vs initial density for CPGurney equation, determining JWL parametersGurney model and Thomas’ synthesisGurney model, fragment velocitiesGurney velocity, casing expansion model

Gumey-JWL energy relationH-6, anomalous inverse sensitivity, LASI

H/I-IN performanceH-19 propellant, characterizationH-6, burning and detonation, gap test

H-6, Hugoniot data for unreacted explosive

Hardness numbers, growth surface of RDXHazard classes, velocities of propellants

Hazard potential, liquid HE, large massHazard response to impact, energetic materialsHBX- 1, density, cd, D, experimental pressureHBX, measured detonation velocity, O-54 kpsiHBX/TNT/Al, v-D curves, wave shape vs DH13X-1, electron~beam initiationHBX- 1 HugoniotHBX- 1, stability & expansion behaviorHeat capacities, calculated, C, O, N, CN, CO, 0,Heat detonations, porous solids, model

Heat of detonation, Cu cylinder test

Heat of detonation, SF~ model compoundHeat of explosion x mass bum = sensitivenessHeat pulse, formation & transmissionHeat release, plane and hemispherical wavesHeat release, rate along shock trajectoryHeat release, vs velocity, gaseous detonation

Heat-sensitive film record, hot spots, shearHeat transfer factor in initiation

5.0295

3.05346.0290

2.06264.05849.05135.03518.06159.0670

6.07677.0655

4.02056.0742

5.0068

9.1480

9.05378.10717.09527.08247.08709.04988.06024.0019

7.08349.04987.02939.04789,10607.0308

5.0251

7.0980

6.0303

6.01229.12433.03765.00732.07337.00509.03795.05232.0239

9.11999.0478

9.11622.06433.05758.01478.01432.02687.09703.0793

.

.

.

s



Heat transfer, from (l?, V, E)Heat-sensitive-film techniquesHeated HE, ESD sensitivityHeats of formation, CN, C,N2, C, N, OHeats of formation, RDX, TNT, ...Heats of formation, maximum rate of bum

Heats of formation, at 298 K, explosives

Heaviside function

Heavy-fragment impact sensitivity, ONTA

Helmholtz free-energy calculation, I-INS

Hehnholtz instability, 2D, fluids’ interfaceHEMP, 2D elastic-plastic code, diverging waveHEMP model, HE charge inside Cu cylinderHeruy model, Gurney velocity, HE casingHerrmann model, compacted porous materialHerrmann model, parameters for 5 porous HEsHeterogeneity, effect on performance

Heterogeneous commercial HEHeterogeneous composite HE (H. C. X.)

Heterogeneous detonation \vave propagation, 2DHeterogeneous HE reaction zone, modelHeterogeneous HE reaction zone, calculated

7.0504

9.08869.10762.02402.0388

2.06838.0808

9.0293

9.1008

6.0751

4.0305

5.04774.05207.08347.04286.07729.01979.0869

8.1011

6.04057.0641

9.0693.

. Heterogeneous HE, thermal ignition & combustion 9.1070

Heterogeneous initiation, SDT 9.0039Heterogeneous shock-heating effect 6.0076Hexatol, hexotonal, hexotolif data 6.0513Hexogen wax/ballistite generator, DDT 7.0157Hexotol, bubble energy, underwater expansion 6.0546Hexotonal, bubble energy, underwater expansion 6.0546High-density inclusions, small thermal effect 6.0336High-density polythene (HDPE) binder 7.0034High-order detonation, onset & transition 3.0517High-order detonation, surface discontinuity 3.0520High-oxygen HE, D vs initial density 1.0028High-speed framing camera, impact initiation 3.0010High-speed particle initiation, azides 2.0565High-temp detonator study, BTX in SE-l 6.0460High-temp effects, time to explosion 3.0060High-temp thermodynamics & gaseous detonation 2.0231High-vacuum detonation, species separation 5.0559High-velocity metal jets 8.0318High-confinement DDT, WC 140, TS3659, WC231 9.0341High-order behavior, diameter effect 9.0197High-pressure activator 9.0003High-rate deformation, HE crystals 9.0058High-resistance manganin foil gauge, det. pressure 9.0471High-speed-machining test of NTO 9.1001

High-strain-rate impact tests, rocket propellant 9.1052Highest energy of energetic composite materials 9.0554Highly localized structures, molecular dynamics 9.0713HMX, 3D hydrodynamic hot-spot model 8.0044

HMX/AINiton, perchlorates, cylinder tests 5,0140HMX/AP mixtures, composite HE model 7,0517HMXIAP mixtures, nonideal detonation 7.0620HMX/AP/ZrH#3stane, mess. of reactive flow 9.0525Hh4X-based customized explosives 7.0566HMX-based PBXS, explosive response, AWRE test 8.1035

I-IMNbinders, explosiveness, L~SET

HMX/binders, explosiveness effect, LABSET

HMX, bubble energy, underwater expansionHMX, chemical decomposition model

HMX, CJ properties, oxygen balance

HMX, confinement influence on sensitivityHMX, content, effect on explosivenessHMX, convective bum at higher pressuresHMX, converging spherical detonationHMX, D (km/s), densityHMX, DDT model, TIGER codeHMX, DDT phenomena in small diameters

HMX, DDT study, plastic tubesHMX, detonation temperature, pyrometerHMX, detonation temperature measurement

HMX, Doppler laser interferometer study

HMX, experimental & calculated CJ parameters

HMX, fracturing data, four porosity levelsHMX, granular, DDT

HMX, HMX/Kel-F cylinder test resultsHMX, hot-spot initiationHMX, ignition data in DDTHMX, impact sensitivity and OB/100HMX/inert, best fits to Taylor wavesHMX, interstitial gas effects on sensitivityHMX, interstitial gases, sensitivityHMX, jet penetration model

HMX, Iaminar to convective burning, DDTHMX, laser ignition test

HMX, mechanical properties

HMX, mixtures with emulsion explosivesHMX, rnonocrystal decomp. vs shock pressure

HMX, nature of hot spots in TATB & HMXHMX/NC/CEF, electron beam initiationHMX/NG & HMX/TNT, light emission testsHMX/nylon, energy threshold, P-t plotHMX, paramagnetic decomposition productsHMX, particle size, effect on explosivenessHMX, particle size distributions, micrographsHMX performance, cylinder test, QHMX, performance model for composite HE

HMX, physical properties, polymers, drop-weightHMX/polybutadiene, sensitivity and performrmceHMX, polymorphs, differing sensitivity

HMX/polyurethane, AWRE EOS method

7.0017

81039

6.05467.0056

8.05477.09668.10353.00777.06028.05148.06727.0107

7.0119

8.05749.0947

8.0135

6.07139.0363

9.02654.00057.03987.02173.06746.06335.02474.0349

8.03377.0164

8.0476

8.0637

9.05459.0172

9.08977.00535.01586.01088.07348.10358.10369.04787.0517

7.0033

8.11323.06657.0679



HMX, porous bed compaction, strain rate 8.0645HMXporous bedresponse, deflagration &shock 9.0280HMX, porous, Pop plot, model vs test data 8.0967HMX powders & polymer HEs, deform. & deton. 9.0886HMX,HMX,

HMX,HMX,HMX,HMX,HMX,

HMX,HMX,HMX,

HMX,HMX,

HMX,

HMX,

HMX,

precursors in detonation

prompt laser initiationpropagation of detonation from impactquasi-static compaction

quasi-static compaction pressurereflection spectra & ignition thresholdretarded detonation, tricks (chicanery)rubber-bonded sheet explosiveself-pressurizing bomb experiments

shock ignition characteristicsshock initiation, tests and modelsspectroscopic study of detonation

steady-state burn rates

surface-melting crystals effect on bum

surface-to-volume ratio

7.0877

9.11109.0798

8.06459.02809.11006.02264.04967.01727.0463

8.0892

8.06917.0219

5.0311

9.0280HMX/TATB/BTF, temperature, cylinder test data 8.1020HMX/TATB, chemical decomposition model 7.0056HMX, temperature, measured and calculated 8.0558HMX, thermal decomposition at P= 10-50 kbar 5.0331HMX, thermal initiation and growth 5.0280HMX, thermochemical data, application to NTOHMX, thermophysical & material property dataHMX, time to explosionHMX/TNT, divergent waves & resonation

HMX/TNT/inert, plate & cylinder driver

HMXflNT/inert, CJ point from velocities

HMX/TNT, polytropic y, energies, velocityHMX/W Hugoniot, p/pc, vs UfUc,

HMX, W-loaded, X-0233, detonation testsHMX/Viton, radius-of-curvature effect

HMX/water, initiation, particle size effectsHMX/wax, surface coat effect on sensitivityHMX, wedge test, smear camera recordHMX, x-ray and infrared studies, bondsHMX, x-t DDT dataHMX/ZnClz, temp. & cone. effect on sensitivityHNA-130, detonation-front temperatureHN/HH, detonation-front temperatureHNA13, Hugoniot data, two densities

HNAB, inititttion by electrically driven flyer

HNAB, polymorphic forms (I, H), thresholdsHNB, CJ properties, oxygen balanceHNB, detonation velocities

HNB, isentrope behavior, fluorine oxidizer

HNB performance, Cu cylinder test, QHNB, postdetonation properties, CJ points

HNDZ, time-to explosion

9.04899.02939.02284.0426

4.0023

4.0056

5.0462

9.03798.09794.0086

9.00254.03993.05117.07799.03065.01859.09399.09397.0416

8.11268.11268.05478.05387.0942

9.04787.0647

9.0228

HNS, chemical reaction, shock-initiated 8.0015HNS, chemistty in free expansion of HE products 9.0953

HNS, CJ properties, oxygen balance

HNS, DDT studies, small diametersHNS, detonation properties, carbon EOSHNS, enhanced temperature and pressureHNS, EOS & chemical kinetics

HNS, fine-grained, reactive model

HNS II, EOS & shock initiationHNS, impact sensitivity and OB/100HNS, in Comp B, reduced thermal hazard

HNS, initiation threshold, high t,HNS, laser ignition testHNS, laser initiation

HNS linear-shaped-charge designHNS MDF, output measurements & modelingHNS, mechanical properties, drop weight

HNS, microstmcture effect on sensitivityHNS, mild detonating fuse output measurementsHNS, optical absorptionHNS powders, isothermal compressibilityHNS, products in pre-ignition reaction zoneHNS, prompt laser initiation

HNS, reflection spectra & ignition thresholdHNS, sensitivityHNS, sensitivity and performance, SDDT modelHNS, shock Hugoniots & initiation thresholdHNS, slapper detonatorHNS, spectroscopic study of detonation

Hollow charges, multiprotlle streak technique

Hollow-sphere configuration modelingHolography, pulsed laser, HMX in DDT

HOM EOSHOM EOS Of PBH-9D

HOM EOS, underwater shocks, Mach stem pressure6,0570HOM-SG EOS, decomposition estimate 6.0025Homogeneous detonations, 2D model 6.0405Homogeneous HE; liquid NO 9.1335Homogeneous HE, SDT theory 9.0219Homogeneous HE, techniques to ensure them 2.0119Homogeneous initiation, SDT, in situ 9.0039Homologous series of polynitroaiiphatic HEs 9.0461Hondo/Krier, combustion model + dynamics code 6.0258HONDO finite-element material code 9.0363Hook effect, comer-turning propagation 7.0625Hook effect, dark zone, rarefactions 3.0802Hook effect, observations, theory, rarefactions 3.0786Hopkinson bar, apparatus, strain rate data 8.0635Hopkinson bar, miniaturized 9.0886Hopkinson bar, modified, tests on rocket propellant 9.1052Hopkins*m bar, shock pressure test 2.0657

8.05477.0107

8.05286.00626.07489.02096.07403.06818.02526.0044

8.04769.1118

9.13859.1519

8.0642

8.0026

9.15107.09359.02099.0162

9,11109.11007.10248.11325.02199.0209

8.06917.0751

9.0906

7,0165

9,07519.0142

.

.

.

58

.

.



Hot boundary of ID detonation wave (sigma) 4.0082Hot-plate and hot-wire sensitivity tests 5.0280Hot-spot formation, collapsing void, condensed HE 9.0906Hot-spot formationHot-spot generation, model of reaction rate

Hot-spot generation & extinctionHot-spot reaction in DDT

Hot-spot residue, physical natureHot spotsHot spotsHot spots, AP, single crystals

Hot spots by dynamic compaction

Hot spots, cavity initiation

Hot spots, Comp B, in-bore explosions

Hot spots, DDT, compaction of porous HEHot spots, decomposition at low pressureHot spots, formation mechanismsHot spots, formation, explosive cgstalsHot spots, frozen, shocked EDC35 IHEHot spots, cause of gas inclusionsHot spots, high rate deformation & shocksHot spots, initiation, varying planar figures

. Hot spots, initiation, microhardness of RDXHot spots, interacting shock in NM, model

Hot spots, low impact & low amplitudeHot spots, model, Al & void in NM cylinderHot spots, model, initiates bulk reactionHot spots, model, heterogeneous HEHot spots, model, reaction centersHot spots, model, void collapse

Hot spots, model, shock-compressed HEHot spots, model, thermal energy, pore collapseHot spots, model, shear band nucleationHot spots, model, cavity collapseHot spots, model, EIvIY velocity gauge dataHot spots, model, reaction spots origittHot spots, model, chemical, pressure loadingHot spots, model, temp dependent, 3 termsHot spots, multiprocess detonationHot spots, reactive porous bedsHot spots, shear bands in crystalsHot spots, shock causes thermal reactions

Hot spots, shocks + density discontinuitiesHot spots, size, critical, propagating NM

Hot spots, slurry HE under impact, modelHot spots, surface burning in porous solidsHot spots, theory, first proposedHot spots, thermally decomposed intermediatesHot spots, time evolution, modelHot spots, volume fractionHot-wire initiation of primary explosives

9.12439.05939.06049.02939.08979.0842

9.08869.1260

9.0341

2.0643

8.02528.08816.0029

6.00698.00629.12536.03367.09707.0797

7.09765.01807.0970

4.03946.03717.03947.04357.05067.0523

8.00268.00358.00688.01908.06788.0926

8.09519.07249.02599.0058

3.05186.0405

4.03957.03433.08013.08428.07259.11936.0372

5.0339

HTPB PBXS, RDX crystalsHTPB/PDL binders

Hugoniot, (theoretical) of metals vs dataHugoniot, brass, pressure vs UPHugoniot calculations, porous reactive materialHugoniot, condensed-phase explosivesHugoniot, data, least-square fitsHugoniot data, various materials

I-h.tgoniot, detonation & deflagration branchesHugoniot, elastic limits in A1-CU aIloys

Hugoniot, equation, detonation productsHugoniot, experiments, SDT, small powder gun

Hugoniot, Insulboard

Hugoniot, lamellar A1-CU composites

EIugoniot, liquid N,, CO,, 0,Hugoniot, low pressure, of solid HE

Hugoniot measurements, rocket propellantsHugoniot, polyurethane foamsHugoniot, reaction productsHugoniot, shock initiation threshoid, Pb(N3 )2Hugoniot, steamHugoniot, unreacted, EOS, c 90 kbar

Hugoniot, unreacted explosivesHugoniot, unreacted porous high explosivesHugoniot, with too much Al, envelopesHugoniots-Rayleigh line intersection, steamHULL Eulerian code, composite HE modelHV4, thermal initiation and growthHW4, growth of reaction, skid test

HW4, thermal initiation and growthHydrazine mononitrate, detonation velocityHydrazine mononitrate, reaction timeHydrazine mononitrate, wax-gap testHydrazine nitrate (I-IN), high-vacuum detonation

9.0083

7.00174.02093.05679.11994.02415.02229.14416.02386.0151

2.03868.0907

3.0401

6.01557.0649

4.02399.10606.04929.03796.03892.03074.02405,02516.0766

1.01142.02987.0517

5.02806.02905.02801.00081.00561.00235.0559

Hydrazine nitratelhydrazine hydrate solution, prop. 9.0939

Hydrazine nitrate/water solution, properties 9.0939Hydrazoic acid, unimolecular decomposition 8.0828Hydrocarbon-air compressed mixtures 9.0933

Hydrocode RUBY, aluminized HMX, perchlomtes 5.0141Hydrocodes, 2DE, hot spots, rare factions 5.0177Hydrodynamic codes, lD & 2D, used with tests 4.0519

Hydrodynamic elastic plastic theory in metals 4.0289Hydrodynamic motion, 2DE shell code 5.0487Hydrodynamic solution, reflected shock, FS 3.0264

Hydrodynamics, HIEX ID model, duration effect 5.0191Hydrodynamics, PHERMEX radiography, rarefact. 4.0642Hydrogen bonding, TATB 9,0153

Hydrogen increases performance > carbon 8.1003

Hydrogen-oxygen, detonation, schlieren photo 2.0284

Hydrogen-oxygen, mixtures, stoichiometric 2.0258

Hydrogen peroxide-glycerol, LVD & HVD, gap 4.0412

59



.

.

Hydrostatic compression instrument

Hydrostatic compression of HE, their productsHydroxyl-terminated butadiene (HTPB)Hypervelocity impact data, steel, Al, PbHypervelocity wave phenomena, condensed HE[deal and nonideal detonationsIdeal gas, adiabatic compression, equationIdeal mixing, accuracyIdeal/nonidetd HE, wave shape measurementIDEX code, adiabatic y & Gt-ihteisen rIgniter compaction of inerts

Igmter effect on DDTIgniters, DDT effects in plastic tubes

[gmters for DDT, Pb304 /tetrazene/B

Igni[ers for KN03 /Zr

Ignition & growth flow, computer modelsIgnition & growth model, 2D LagrangianIgnition & growth model, DYNA2DIgnition & growth model, LX-17Ignition & growth model, porous HEIgnition & growth model, propellant cracksIgnition & growth model, SDT, composite HE

[gnit~on & growth model, TATB EOS[gnitlon & growth model, three terms, PBX

[gmtlon & growth of reaction, summaryIgnition & growth rate, LX-17, velocimetryIgnition & growth reaction rate law, 2ND modelIgnition by rapid compression of air

Ignition energy vs pressureIgmtlon mechanisms, launch environmentIgnition studies, mechanical & chemical

Ignition tests, RDX/TNTIgmtmn thresholds, TNT, LX-14, Comp A-3

Igmtlon vs buildup, SSGT, Australian

Ignition wave in DDT, HMXIHE EDC35, effect of wall on detonation velocity[HE EDC35, frozen hot spots in shocked

IHE gap test, EDC35 (95 TATB/5 Kel-F)IHE gap tests, (ELSGT) at AFATL[HE lab-scale sensitivity testingImage dissection multiple-frame photographyImage intensifier camera, multiple exposureImpact (plate) initiation, RDX/TNT modelImpact-face stress recordsImpact hazard response, energetic materialsImpact heights (50%) vs OB/100 valuesImpact ignition modelImpact initiation, critical conditions

Impact initiation, low-order explosives

Impact initiation, military explosivesImpact initiation, HE crystals

9.1295

6.07007.0017

8.11533.03048.09882.05849.04432.05009.05137.0843

9.0320

7.0143

9.0320

9.03209.07017.04887.1035

9.01127.02347.01869.05938.05888.09024.05129.01339.06707.0003

9.0162

9.14604.0477

8.02559.1460

9.00989.02659.08319.1253

9.01239.12847.09652.01696.06648.01987.0867

9.12436.03177.04597.0316

6.0325

2.06129.0058

Impact initiation, HEs by projectile

Impact initiation, propellantsImpact-loaded void modelImpact, low-velocity projectile, composite HEImpact machine, ERL, high rate deformationImpact machine, framing-camera studyImpact machine, sensitiveness testsImpact on heavily confined HE targetsImpact on HEs, spherical projectileImpact phenomena, explosives & propellantsImpact region, propagation of detonation from

Impact response, confined charges

Impact response, flat & round-nosed vs code

Impact response, fragment attack

Impact response, instrumented shotgun testsImpact response, low amplitude & low impact

Impact response, molecular dynamics studyImpact response, small cylinders, thresholdsImpact response, two mechanismsImpact sensitivity & OB ,W, 78 ExplosivesImpact sensitivity, critical air gapImpact sensitivity, machine, colliding ballImpact sensitivity, organic HE structure

Impact sensitivity, oxygen balanceImpact sensitivity, tests, EA eutecticsImpact sensitivity, thermal explosion timeImpact, tandem and axisymmetric, propellantImpact with transient confinement

Impacting surfaces, aligning & adjusting

Impedance effects on detonation failureImpedance match determines particle veloci~

Impedance matches, shock wavesImpedance matching effect, measured det. T

Impedance matching plate & HE, reflection = OImpedance-mismatched systems

Impulse & energy fluxes, calculatedImpulse time integral, PBX 9502

Impulse-gauge data, PBX 9502In-bore thermal explosions, Comp BInclusion geometxy effects on initiationIndexes of Detonation Symposia, 1951-1985Induction period, gaseous detonationInduction period, memory effectInduction test, safety analysis modelsInduction time ~ vs thickness of inclusionsInduction time dependence on shock pressureInduction zone in TNT, variable densitiesInert additives, effect on HE

Inert binder effects on cast-cured PBXInert gas effect in gas reaction zoneInert-HE interface, decomposition effect

9.1441

9.1052

7.0783

9.10477.0970

3.00103.06608.02949.14276.03369.0798

8.02627.0325

7.1048

7.02997.0970

7.07837.0273

8.11506.03142.06283.0001

6.03123.06937.05483.00698.02875.0279

5.0384

8.03785.0251

7.0908

909471.0091

2.03636.05579.0683

9.06838.02514.03869.15431.00493.00429.10704.03893.04872.03705.04647.0560

2.01966.0029

.

.

-4

60

.

.



Inert solids, shock wave research on 4.0321Iner[ witness foams, low-density HE systems 6.0183Infinite confinement for Nh4 in metal tubes 2.0455Infinite confinement in 0.1 -in. Pyrex tubes 2.0439Intlnite diameter detonation velocity, CZN2 2.0236Infinite diameter detonation velocity, TNT 3.0327Infirute diameter velocity, Al concentration 6.0124Infinite diameter vs density, deviations, TNT 3.0345Influence on detonation, polymorphous transform. 9.0766Infrared radiometry, time-resolved 7.0993Infrared-sensitive photomultiplier tube 5.0339Infrared spectra, NM, high-pressure 5.0331Initiability test, HMX by PBX 9404 8.1064Initial decay time constants, underwater 6.0556Initial temperature vs burning-front velocity 9.1070Initiating power vs sensitiveness, D 2.0608Initiation & propagation, primary HEs 9.1100Initiation, adiabatic cavity compression 2.0645Imtiation by adiabatic shear 9.0886Initiation by electron beam of TATB HEs 9.1131Initiation by fracture, plastic flow & void collapse 9.0842Initiation by impact, propellants

.Initiation, centering device.Initiation, criteria, particle velocityInitiation, criteria, pressure vs pulse length.Initiation, delayed, opaque rare faction zoneInitiation diagnosis, shock, 2-DInitiation, gradients in metastable compoundInitiation, ignition & growth summary

Initiation, IHE by low-amp compressionInitiation, impact, excitation & dissociationInitiation, impact, HE crystals

Initiation, laser, secondary HEs

Initiation, liquid NOInitiation mechanism, jet on covered HEInitiation model for heterogeneous HEsInitiation, molecular crystal (MD)

Initiation, multipoint, slab, optical data vs xrayInitiation, NM homogeneous & heterogeneousInitiation depth vs brass u=Initiation of fast decomposition in solid HEInitiation of HEs by projectile impactInitiation, particle-size effects, HMX

Initiation phenomena, shaped-charge jetsIrutiation, plastic flow, fracture, friction, voidsInitiation, porous propellantInitiation process, Lagmngian gauge study, EAKInitiation, prompt laser, secondary HEs

Initiation properties, 95 TATB/5 Kel-F 800Initiation, shock, LX- 17 vs temperatureInitiation study, time-resolved spectrometry

9.1052

8.03366.00717.04293.04689.00773.08424.0512

6.01159.1084

9.00589.1118

9.1335

9.14049.06048.08709.13609.00393.05679.08579.14419.00259.1416

9.08578.02939.00899.11109.01239.01129.0172

Initiation threshold experiments, IHEInitiation threshold, small flyer-plate experiments

Initiation, transient in dilute explosivesInsensitiveness vs oxygen balance, CHNO HEInstability of interface, two fluids

Interacting detonation waves in condensed HEIntercrystalline friction

Intercrystalline potential, HE crystalsInterface calculation, Al/HE, acoustic approx

Interface equation solution, graphical modelInterface instabilities, Lagrangian mesh

Interface velocimetry, PBX 9502Interface velocity historiesInterferogram of reactive Mach stem in gasInterferometer development, Doppler shiftInterferometer quadrature signal

Inter ferometry, gauge risetime in PMMAIntermolecular HE, EA eutectic testsIntermolecular HE, EAK, wedge testsIntermolecular HE EAK, Lagrange gauge studyIntermolecular HE, prospects

Intermolecular HE, reaction, EMP gaugesIntermolecular HE, small divergence

Intermolecular potential parameters, HE productsInternal cavities in sample, setback simulatorInterstitial gas effect, low-density compactsInterstitial gas effect, sensitivity & timesIntragranular stress, compaction of inerts

Intragranular stress vs plastic strain rateInverse method, CJ pressure,Inverse multistreak technique, WH symmetry

Iodine in HZ-OZ, light absorption of frontIon-exchanged explosive (EIE), axial fuse

Ion probe assembly, diameter effect tests

Ionization & piezoelectric gaugesIonization in shock initiationIonization pins for DDT experimentsIonization probes in DDT studiesIR absorption, NM, diamond-anvil cellIR absorption spectra, TATBIR emission, temperature of shocked HEIron-Constantan thermocouples, NM temperature

Iron, elastic precursor & shock wave photosIsentrope, anomalous, RUBY programIsentrope pressure effect on cylinder testIsentropes, X-0233, gamma law and BKWIsentropic compression, perpendicular driveIsentropic expansions

Isentropic unsteady 3DE flow, surface, modelIsobar cross sections, triple waveIsobars, isotherms, isows, NM calculations

9.11319.0066

7.04483.06974.0305

4.01549.0857

9.00584.05245.02544.0316

9.06578.01234.00716.06738.04687.1063

7.05488.1001

9.00899.05548.0187

8.0176

9.05139,14804.03495.02477.0843

8.06455.00757.0751

2.02174.0156

4.00972.02013.01509.02599.03209.10{99.01537.09932.04564.05694.01684.00078.09836.06086.07174.00787.06725.0179

61



Isomeric cast primary explosives, DDT studies

Isophorone di-isocyanate (IPDI) binder

Isothermal compression of HE & their products

Isotherms, gas bubbles in radius-time planeJA~, detonation characteristics

.Jacobs-Cowperthwaite-Zwisler (JCZ) EOSJacobs equtttions of stateJacobs-Roslund formula threshold velocityJCZ EOS, detonation products, TIGER codeJCZ EOS, single species for hydrocodesJCZ3 EOS, dense gaseous HEs

JCZ3 EOS, for TIGERJCZ3 EOS, postdetonation behavior model

JCZ3 EOS, quatuor model.lCZ3P EOS, detonation properties of CHNO HE

Jet initiation, characteristics, bare HEJet initiation, Comp BJet initiation, confined acceptor charges

Jet initiation, conical shaped chargesJet initiation mechanism, covered HEJet initiation, solid explosivesJet initiation, vs 2DE, FOREST FIRE models

Jet p$metration equation, covered, bow shockJet penetration of HMX and TATB, modelJet penetration velocity vs run to detonationJets from single-cavity collapseJets, shaped-charge, initiation phenomenaJetting interaction of detonating grainsJones & Eyring theories contradictedJones & Krier porous-bed dragJones nozzle theory for unconfined explosives

Jones’ detonation theoryJones’ EOS for detonation gases

Jones-Krier flow-resistance lawJones-Wilkins-Lee EOSJump conditions, boundary of piston, reactiveJump conditions, flow velocity in shockJump distance, gamma, mean free path

JWL calculation, HE parametersJWL coefficients, reactive modelingJWL EOSJWL EOS, coefficients, interferometer testJWL EOS, cylinder test data & ELA codeJWL EOS, detonation performance in HMX

JWL EOS formsJWL EOS, LX-17.IWL EOS of PBH-9D

6.0231

7.0017

6.07006.0342

9.05376.0163

6.01627.03326.01627.0721

9.09336.01667.0646

8.07657.0713

8.03237.0352

9.1416

8.10919.14048.03187.04799.1404

8.03379.14049.08699.14167.08852.0451

9.03632.04831.00261.00769.03299.02934.05031.00544.0194

8.09479.1217.9.06708.05967.06788.09149.07019.01339.0142

JWL EOS parameter determination, Gurney equat 9.0498JWL EOS, parameters 8.0909.lWL EOS, pinned wedge tests 9.0025JWL EOS, porous HNS 90~09

62

JWL EOS, reaction rate parameters 7.0488

JWL EOS, vs data, lD calibration, Comp B-3 5.0008JWL isentrope, P-V, three terms 8.0598K-W (Kistiakowsky-Wilson) EOS, CJ, pentolite 4.0027K-W EOS, applicability to product gases 4.0173Kamlet’s method, explosive perfomnance 7.0952Kantrowitz relation, shock path equation 2.0301KDNBF, Mie-Grtineisen EOS, electron beam heat 5.0352Kerr-cell photos, NM transverse-wave effects 6.0415Kerr-cell camera development 1.0031KHT EOS, equilibrium calculation at CJ state 8.0997KHT EOS, QUATUOR model 8.0764Kihara-Hikita EOS, revised (KHT) 8.0548

Kim’s model of gas generation 9.0329Kinetic lattice model, heterogeneous HE 6.0344Kinetic parameters, N-nitro, C-nitro compounds 6.0318Kinetics of detonation with solid reactant 1.0107Kirkwood propagation theory, CJ conditions 1.0107

Kirkwood theory, shock wave parameters 1.0008Kirkwood-Wood discussion, von Neumann’s model 2.0312KistiakowsL~-Wilson (KW) EOS, performance

Kistiakowsky-Wilson EOS, model of solid HEKistiakowsky-Wilson EOS for Comp B, cyclotolKistiakowsk.c-Wilson equation for parametersKistiakowsky’s theory of initiationKIVA hydrodynamic & chemistxy codeKnoop testing, plastic anisotropy, crystalKoenen test, sensitivity & risk evaluationKP/Al, deflagration velocity, electric probe

Krakatoa model, delayed detonationKrakatoa shock initiation model, lD & 2DKrier/van Tassell gun combustion code, DDTKWB EOS for 50/50 TNT/ANLaboratory-scale explosiveness test, LABSETLABSET setup, explosiveness test

Lagrange 1D model, gas flow, compaction, ,,.Lagrange analysis, shocked TATB

Lagrange analysis technique, ChineseLagrange finite-difference method, How

Lagrange gauge, EA-based explosiveLagrange gauge, in situ casting, flow model

Lagrange gauge, studies, flow fieldsLagrange particles, phase trajectoriesLagrange sound velocityLagrangian 1D finite difference code, WONDYLagrangian 2D model, cylinder, LVD impactLagrangian 2D unsteady model of impactLagrangian analysis, MIV gauge, PBX 9502Lagrangiwt analysls of EMV experlmen[sLagrangian analysis of pressure measurements

Lagrangian analysis, reaction rates of PBH-9D

3.07252.0383

3.07211.00301.00579.09567.09776.02744.0616

8.01358.08926.02582.05208.10358.1037

8.09147.0386

8.0083

4.03178.01117.10727.04988.02017.07917.03945.03136.03369.06839.US1691~17

90142

.

.

.

.

.

.



Lagrangian coordinates, porous HE model 7.0442

Lagmngian coordinates, slurry HE model 7.0344

Lagrangian gattge studies 9.0252Lagrangian gauge study of initiation 9.0089Lagrangian gauges, 2D 9.0816Lagrangian mesh 2D calculation, instabilities 4.0316Lagrangian wave propagation models, NM 7.0609Lame’s constants, elastic strain rate 4.0296Lamellar composite materia 1s (AI-C U), shocked 6.0151Laminar-convective bum, porous, crystalline 7.0164Laminar reactive flow, confined HE 7.0958Large-caliber charges, TNT, NQ, AN, Al 8.0577Large-scale gap test, LSGT, critical diameter, TNT 5.0207

Large-scale gap test, numerical modelLarge-scale gap test, NSWC, pentolite/lWMALarge-scale gap test, model, test setup

Large-scale gap test, TATB & HMX mixturesLarge-scale gap test, comelating other testsLarge-scale blast-pad test, NG/~-lactoseLarge-scale gap test, benzofuroxansLaser beam flux calculationLaser beam shock in solid deuterium

Laser ignition of HEs, preignition reactionLaser Ignition of HEs, Raman spectroscopy

Laser ignition test, sensitivity calibrationLaser-initiated decomposition, spectrographyLaser initiation, insensitive high explosive

Laser initiation, lead azide crystalsLaser initiation of seconda~ HEsLaser initiation, prompt, secondary HEs

Laser interaction: damage to materialsLaser interferometry, liner deflection

Laser-probe mass spectrographyLaser Raman spectroscopy, ignition zoneLaser-speckle & Brazilian testLaser speckle, tensile strength and strainLateral expansion, Prandtl-Meyer flow

Lateral rarefactions, oblique impact effects

Lateral shock pressure in cylindrical chargeLattice deformation, HE crystalsLattice density of states in HELattice dissociation, 2D systemsLattice structure, CJ products, high densityLaue back-reflection photo, RDX crystal

5.04776.07687.04807.05697.0888

9.09729.05667.0797

5.03619.01629.1151

8.04738.07106.06127.07359.11189.11106.06138.05969.0172

9.11519.0886

8.06356.0602

5.05784.00929.00589.02357.07812.04057.0978

Launch environment, sensitivity of HEs to ignition 9.1460LAX method, discontinuities in 1D hydrocodes 3.0615LAX method, unsteady 1D flow 3.0534Layzer’s solution, acceleration, 2 fluids 4.0305Lead azide, ~, laser initiation 7.0735

Lead azde, CJ det%gration model, DDT study 6.0244Lead azlde, crystal size effects, size effect 2.0561

Lead azide, DDT study

Lead azide, decomposition reaction

Lead azide, de flagration in single crystalsLead azide, electric field initiationLead azide, environmental shock test

Lead azide, fast burning, impact machine

Lead azide, high-vacuum detonationLead azide, hot-wire initiationLead azide, Hugoniot & shock initiation, gun

Lead azide, linear memory effectLead azide, precipitated with polyvinyl alcoholLead oxide effect in RDX/TNTLead spread orientation effect in tests

Lead styphnate, bum rate, sensitiveness, QLead styphnate, DDT studyLead styphnate, hot-wire initiation

Lead styphnate, laser initiation studyLead-foil electrostatic testing techniqueLeast-squares method, rate stick testsLennard-Jones-Devonshire EOS, gas & liquidLennard-Jones-Devonshire free-volume EOSLennard-Jones parameters, calculated velocity

1.0060

2.0529

5.03016.03903.00243.00105.05615.03396.03893.00472.07115.04657.1065

2.06511.0060

5.0339

8.07109.1076

2.01311.01082.0389

2.0237Less-sensitive HEs, capture of detonation products 9.0962LI/MS laser-ignitecVmass spectrometty

Liahov equation for slurry HE densityLiF effect on Comp B’s acceleration of metalLiF-HE interface detonation productsLiF, “material property valuesLight emission, compressed gas around chargeLight emission, initiation of liquid HELight-gas gun experimental setupLight-gas gun, multiple shocks to TNTLight-gas gun, supracompression, TATB EOSLight initiation of crystalline azidesLight intensity at charge-Perspex interfaceLight patterns in powder & plastic HE, photos

Light pipe, detectors of hot-wire initiation

Light-scattering processes, schematicLindemam theoryLinear bum rate, theory & calculationLinear shaped charges, design & developmentLiner deflection, symmetric, interferometerLiner velocity, interferometer dataLiner velocity vs polar angle, pins in spheresLiquid HE, 36 new, characterization studyLiquid HE, cavitation effectsLiquid HE, decomposition, thermal explosion

Liquid HE, detonation, hot spot model

Liquid HE, initiation & growth of detonation

Liquid HE, NM failure process

Liquid HE, sensitiveness, Q, m

9.01627.03466.05108.01338.00653.02035,01536.00167.0907

8.05872.05474.0431

6.042?5.03407.1011

902353.06559.1385

8.05968.05976.05246,04667.03736.0029

8.0678

30436

2.0462

2.u648

63.



Liquid HE, sensitiveness, m x QLlquld Hugomot, universalLiquid NO, initiation & detonationLithium niobate pressure transducers, aquarium

Logosphere explosive device, setupLong pressure pulses, 102mm gun tests

Lorentz-type electromagnetic gaugesLow-amplitude shock initiation (LASI) test

Lotv-amplitude shocks, hot spotsLow-density explosives, D, P, CJ conditions

Low-density HE systems (<0.25 g/cm3)Low detonation velocity, HMX/AP/Al

Low-energy laser initiation, lead azideLotv-impact tests, hot spots generated

Lo\v-order behavior, diameter effectLow-order decomposition (sympathetic deton.)Low-order detonation, cavitation, NG/EGDN

Low-order detonation, early historical workLow-order detonation, rapid bum, steady stateLow-order detonation, TNT, particle sizesLow-order initiation, resonation, Comp BLow-order initiation, velocity vs mass

Low~order reactions in shocked explosivesLow-pressure effect in DDTLow-pressure HEs, PETN/polyurethane foamLow-pressure Hugoniots of solid explosives

Low-pressure points on isentropes of HELow-velocity, ID impact on shocked solid HE

Lotv-velocity impact, compressive combustionLow-veloclty impact, granular materials

Low-velocity, impact initiation, anvil testLow-velocity, impact, SUSAN test

Low-velocity, nondetormtive explosionLSC, linear shaped charges, collapse & jettingLSCAP code, linear-shaped-charge analysisLucite, shock velocity vs shock pressureLuminosity, detonation flamesLummosity, radiation energy, for detonationLummosi[y-time curves, detonation temperature

LVD, cavitationLVD, condensed HELVD, DDT studyLVD, gas effects

LVD, HVD in liquid HE, card gap testLVD, HVD in ureaperchlorate mixturesLVD, liquid HE, cameraLVD, methyl mtrateLVD, NG-EGDN, cased

LVD, mtromethaneLVD, NM, windows

LVD, screening test

64

2.06999.00399.13357.1016

8.01528.00119.07667.0285

7.0973

5.00476.01837.06207.07357.0971

9.01973.0520

3.0451

3.07863.06072.04793.08336.0328

4.04627.01439.13644.02393.03864.0239

9.02599.02934.0473

4.04777.0248

9.13859.13853.03722.05711.00152.01587.0373”

6.03446.0250

2.05824.04126.04504.01175.0267

5.00817.05754.01266.0470

LVD, wall effectsLVD, wall effectsLVD, wave stability, testsLVD, witness platesLX-04, -07 cylinder test resultsLX-04, curvature radius effects

LX-04, low-velocity impact sensitivity, pinchLX-04, measured detonation pressure, aquarium

LX-04, thermal decomposition of confined HELX-04, underwater shock-to-bum tests

LX-06, measured detonation pressure, aquariumLX-07, cylinder test results, 2-in. diameter

LX-07, EOS above CJ pressureLX-07, measured detonation pressure, aquarium

LX-10 booster for LX-17LX- 10, cylinder test results, 2-in. diam.LX- 10, measured detonation pressure, aquarium

LX- 10, thermal decomposition of confined HELX- 14, CJ adiabats, HugoniotsLX- 14, dynamic high-resolution testsLX-14, EOS

LX- 14, ignition threshold

LX- 14, postdetonation behavior theoryLX- 17, 2D ignition model, comer turningLX- 17, calculated & test particle velocitiesLX- 17, EOS above CJ pressureLX- 17, Fabry-Perot velocimetry

LX- 17, shock initiation vs temperature

LX- 17, supracompressed, reaction-zone structureLX- 17, TATB compositions, initiation studies

M2, detonation characteristics

M29 & M47 detonators, PVA lead azideM30, Al bum rateM30: chemical reaction, fracture resultM5, detonation characteristicsMA, liquid HE, characterizationMaceks model, modified, for DDT in cast HE

Mach bridge, cfitical angle, shock wavesMach bridge, interacting twin spheres in waterMach bridge, Whitham’s method modifiedMach detonation disk, UFD charge designMach detonation wavesMach detonation waves, formation conditions

Mach interaction, critical angleMach interaction, two interacting wavesMach interaction, two plane detonation wavesMach phenomena, continuous observationMach reflection, air shock after impactMach reflection, HE-inert interfacesMach reflection, condensed explosiveMach reflection, detonation waves

4.01174.01265.00816.04734.000540088

4.04785.0065

6.02144,0489

5.0065

5.01408,05875.0065

9.01335.0140

5.00656.02148.05048.06139.0425

9,14608.05017.04887.10348.05879.01339.0112

9.0670

8.1045

9.05372.07127.0899

8.02439.05376.04676.02366.0489

505854.0142

9.04071.00404.0135

6.04984.01384.01428.043 I8.10759.08424.015470669

.

.

.

.

*



Mach reflection, diagrammatic sketch 1.0080

Mach reflection, iron 4.0153

Mach reflection, oblique flow across shock 6.0571Mach reflection, detonation waves 7.0796

Mach stem, in water, parameters, data & model 6.0582Mach stem, zero & nonzero growth angles 6.0574Macrokinetics equations of decomposition 7.0362

Macrokinetics of shock-wave decomposition 9.0050

Magnesium, elastoplastic release at 80 kbar 4.0290Magnetic & electric fields in detonation 3.0844

Magnetic flux compression generator source 7.0746

Magnetic gauging experiments 9.0039

Magnetic probe data, particle velocities 7.0534

Magnetic probe measure of particle velocities 6.0637Manganin foil gauge 9.0003Manganin gauge, high resistance, detonation press. 9.0471

Manganin gauge, multiply embeddedManganin gauge, pressure records, dimple testManganin gauge, records, low-order detonationManganin gauge, setup, recordsManganin gauge, setup, low resistanceManganin gauges in TNT & RDX

.Manganin gauges, multiple

Manganin-constantan ring gaugeManganin-constantan ring probeMansoori-Canfield-Ross procedure, polyatomicMapping failure waves in liquid HE detonation

Mass displacement moment, PBX 9502

Mass fraction contours, PBX 9502, comer

Mass fraction contours, from 2DE model

Mass fraction profiles, X-02 19 in air, 2DMass motion in detonation products (ASM)

Mass points in HE, marked, x rays, analysisMass rate of combustion, sensitivenessMass spectrometer, detonation productsMass spectrometer study of detonation productsMass spectrometry, fast-transient kinetics

Mass spectroscopy of HE, preignition reactionMatrix properties, shock sensitivity

McSkimin phase comparison technique, transitMDF, HNS, output measurements & modelingMDF, mild detonating fuse, HNSMechanical properties, effect on explosiveness

Mechanisms for jet initiation of HEMedina, impact sensitivity and OB/100Melamine, compaction in porous bedsMelt kettle design, homogeneous HE chargesMelt line, carbon

Memory effect, thermal initiationMercuric-s-nitrotetrazoie, initiationMercury fulminate, burn ra[e, Q, m x Q

6.0021

8.10856.03306.06257.0386

9.00509.0025

9.08169.00777.06485.0115

9.0683

8.0059

8.0314

6.04115.0447

5.00032.06438.07019.09539.1140

9.01625.01826.03989,1519

9.15108.10379.14043.06747.0843

2.01219.04173.00429.11002.0651

Mercury fulminate, contact film record

Mercury fulminate, deflagration before DDT

Mercury fulminate, initiation & propagationMercury fulminate, laser initiation studyMercury intrusion porosimetry, TATBMesh-initiated detonator, MFG as source

Me[al (Al) foils, electrically explodedMetal acceleration by chemical explosivesMetal acceleration by composite HE

Metal combustion in composite HEsMetal-semiconductor blocking contact, E level

Metallurgical properties, shock propagation

Methyl-5 -nitrazole (1 -MNT) & (2-MNT), DDTMethyl nitrate & mixtures, detonability

Methyl nitrate, bum rate, sensitiveness, QMethyl nitrate, diluent effect on NM

Methyl nitrite, shock initiation, gap testMethylnitramine, molecular geometry, ab initioMF, liquid HE, characterizationMFDNB, liquid HE, characterizationMFF, liquid HE, characterizationMichelson-Ray leigh line, P-V plane

Micro-indentation studies, unshocked HE crystalsMicroballoon concentration, NM-PMMA deton.Microballoons, emulsion HE, performanceMicroballoons, NG, initiation effectsMicrocracks in cast HE, bum rate effect

Microflash photography, impact on propellantsMicrographs, shear and fracture damage

Microhardness study, RDX, deforming hot spots

3.0010

1.0058

9.11008.07108.00037,0746

6,06534.()()035.0137

9.0641

6.03914.0295

6.0231

5.02672.0651

7.05835.0237

8.0828

6.04676.04676.04677.0791

9.12609.09258.09933.04607.0904

9.10528 o~97

7.0976

Microphotography, metal combustion, compos. HE 9,064 IMicroscopic processes, simulationsMicrostructure effect on sensitivityMicrostructure, PBXSMicrowave interferometer, wave form, TNTMicrowave interferometry techniquesMicrowave interferometry techniques

Microwave technique for detonation velocities

Microwave velocimeter, HE-filled waveguideMie-Gtineisen EOS, theoryMie-Griheisen EOS, detonation productsMie-Griineisen EOS, unburned materialMie-Grtineisen EOS, shock loading Cu & UMie-Grttneisen EOS, HE & detonation productsMie scattering, from shocked benzene spectraMie-GrOneisen EOS for DDT

Mie-Gritrteisen equationMild detonating fuse, modeling & output

Militaxy explosives, impact initiationMimimum priming charge test, correlationsMinimum detonator test for sensitiveness

9.07138.t20269.08863.01474.05848.0485

2.01512.01514.02055.00675,0196

5.03527.03629.0190903299.00509.15102.06127.08882.0602

65



Minimum priming charge test, model 7.0479Mimmum priming charge test, assembly 7.0698Minimum priming charge test, propellants 8.0285Minimum priming charge test, model 8.0954Mimmum shock-loaded surface area 7.0316Minimum shock pressure to start reaction 6.0003Mmmg safety HEs, detonation & failure 9.1351Minol-2, curvature effect on shock wave 1.0099Minol, low-order reactions--reaction zone 4.0462MIV gauge experiments, PBX 9502 9.0683Mixer circuit, capacitors & resistors, D 2.0139Mixing thermal model, heterogeneous reactants - 9.1199

Mixture EOS 9.0670Mixture theory, HE EOS 9.0443Model calculation of HMX porous-bed response 9.0280Model, DDT in porous beds 9.0363Model for dislocation, HE crystals 9.0058Model for initiation of heterogeneous HEs 9.0604Model for spherical projectile impact on HE 9.1427Model, multiprocess detonation 9.0724Model of 3D, spinning detonation wave front 4.0074Model of reaction rates in shocked HEs 9.0593Mo&1 of shock initiation 9.1224Model, thermochemical, shock-induced reaction 9.1199Modeling a spherically-expanding Comp B deton. 9.0751Modeling by mathematical morphology theory 9.1271Modeling detonation waves, deton. shock dynamics 9.0730Modeling gap tests, sensitivity vs compressionModeling HNS MDF outputModeling, mild detonating fuse output

Modeling of thermal ignition & combustionModeling, reacting media, choice of equations

Modified gap test, mechanical shocks, 27 HEs

Modified steel DDT tubeMolecular beam, freely expanding HE products

Molecular collision excitation & dissociationMolecular/composite explosivesMolecular dissociation, effect on deton. structureMolecular dynamics (MD), diatomic crystalsMolecular dynamics (MD), exothermic crystalsMolecular dynamics, JCZ EOSMolecular dynamics methodsMolecular dynamics methodsMolecular dynamics simulation of deton. structure

Molecular dynamics simulations, N, & CO,Molecular initiation, Buckingham potentialMolecular initiation, seconda~ explosives

Molecular kinetics, V & P dependenceMolecular models for HEs, NTOMolecular orbital calculations, ab mitio, HEMo[ecular orbital calculations, C-N bond scission

66

9.14519.15199.1510

9.10709.02509.1235

9.03549.0953

9.10849.05459.07138.08648.08707.07217.07777.07899.0713

8.05317.07167.0065

6.03059.1185$.08279.1027

Molecular population behind shock wave 9.0172Molecular properties, gamma sensitivity to errors 9.0513Molecular reactivity, HEMolecular subignition, underwater shockMolecule-surface collision-induced dissociationMonel bomb walls, HF-producing HE

Monomethylamine nitrate (MMAWJ) sensitivityMonomodal cast PBX formulations, RDX

Monomodal formulations, particle effectMonomolecular decompositionMonopropellant, card gap sensitivity testMonopropellant, reaction modelMonte Carlo and theoretical isotherms

Monte Carlo method, detonation product EOSMorphology of grains, effect on HE behavior

Moving dislocations, HE crystals

MRL & NOL SSGTMultiboundmy HE geometry, 2D program

Multidimensional detonation waves, modelingMultiinitiator explosive initiationMultilayered shields, impedance variationsMultilayered shields, sympathetic detonationMultiphase detonation, fuel-airMultiphase mixture model, granular materialsMultiple-exposure image-intensifier cameraMultiple flash gap, detonation pressureMultiple-gauge studies, in situ EMV systems

Multiple Lagrange gauge experimentsMultiple Lagrange gauges, condensed HEMultiple Lagrange gauges, TNT

Multiple-shock calculations for PBX 9404Multipoint initiation

Multiprobe detonation buildup tests

Multiprocess detonation modelMultiprofile streak technique, WH symmetry

Midtistreak camera record, shaped chargeMultistreak technique, detonation frontMunitions accidehts, analysis and testsMunitions performance, Q, Cu cylinder testMunitions, propagating detonation modelMunitions, shielding, sympathetic detonationMunroe jet, formation & equilibrium in x myMumaghan EOS and exponentMurnaghan EOS, constants for C-7, Al, Cu, AuMurnahan solid compressibilityN-NOl, time-to explosionNz, liquid, vibrational spectroscopy

Nz liquid, shocked, vibrational spectroscopyNavier-Fourier fluidNb powder, polarization & relaxation signalsNB-40, experimental vs computed Hugoniots

9.02468.07259.10847.0942

7,03738.0903

9.00186.03063.08227.0517

8.0523

9.04529.1271

9.0058

9.00989,0730

9.07307.06718.11439.1489 .7.07999.02936.0664 .7.04097.10629.00897.10726.07868.1063

9.13605.0249

9.07247.0751

8.04648.03308.02119.04787.10559.14894.06447.0503

4.02799.02099.02289.0180

9.01729.02466,01456.0772

.

.



NC, detonation characteristicsNC, effect, chemical decompositionNC, mechanical properties, drop weightNC/NG detonation characteristics, low densityNC, nondetonability through transition

New, more powerful HE, predicting, VLW EOS

NF~ calorimetry studies

NG, BKW model & performance data

NG, bubble-free, low sensitivityNG, bum rate, sensitiveness, Q, m x QNG, CJ properties, oxygen balanceNG, detonation flame analysisNG/EGDN, gap test, camera recordNG/EGDN, low-velocity detonationNG/EGDN, LVD & HVD in liquid HE, gap testNG/EGDN/Ta, shock sensitivity gap test dataNG, high- & low-velocity deton., aeration

NG, light emission in initiationNG, polarization & relaxation

NG, radiance, detonation temperatureNG, sensitiveness, m x QNG, sensitiveness, Q, m.NG, streak camera record, 5 .2cm-diam cylinder

NG, time delay vs reciprocal temperature

. NHz deformation modes, TATBNIP model, plane-wave-dri~ring plate, spanNitramine burning rates, high pressureNitramine decomposition, EPR spectraNitramine HEs, decomposition mechanismsNitramine propellants, gas phases in DDTNitramines & nitramides, sensitivity tests

Nitramines, electronic structure

Nitramines, impact sensitivity vs OBNitrate ester (aq.), threshold v, bum rate

Nitrate HEs, decomposition mechanisms

Nitric esters,

Nitric oxide,Nitric oxide,Nitric oxide,Nitric oxide,Nitric oxide,Nitric oxide,

electronic structures

CJ properties, oxygen balancedetonation characteristicsdetonation propertiesdetonation velocitiespostdetonation propertiesstatic high-pressure study

.

u

Nitro HEs, decomposition mechanismsNitroaliphatic compounds, sensitivity vs OBNitroaliphatic HE, heats of detonationNitroaliphatic HE, impact sensitivity & 0!3 ,WNitroaliphatic HE, thermal decompositionNitroaromatic compounds, OB ,M, sensitivity

Nitroaromatics, electronic structure

Nitrogen, equivalent equationNitrogen, isotherms and Hugoniot

5.00477.00588.0642

5.00473.06369.0435

7.0940

3.0728

3.04552.06518.05472.05733.04404.oli74.0412

4.04162.05825.01536.01447.0762

2.0699

2.0648

3.0814

3.00689.01534.05389.13108.07349.10277.0217

3.06737.0065

3.0696

6.0119

9.10277.0065

8.05476.07238.04228.05387.06478.07159.1027

3.06966.03207.00875.03313.06807,0065

8.10118.0534

Nitrogen, phase changes, effect on detonationNitrogen, test & calculated HugoniotNitroheterocycles, ammonium salts

Nitronyl nitroxyl radical, decompositionNitrosol, density, shock & particle velocities

Nitroxy radicals of HEs

NM & NMfTNNI, BKW model & perform. dataNM & NM/TNM gap test results, sensitivity

NM, 2DE model, failure & shock initiationNMlacetone detonations, fine structureNM/acetone mixtures, wall traces of detonation

NM/acetone, triple-point trajectoriesNM, aquarium tests, photos of failure wavesNM, ammonia complex calculationsNM, brightness temperaturesNM, bubble energy, underwater expansion

9.0425

8.05517.0801

8.07404.02459.09873.0728

4.0417

5.01777.095s5.0105

5.01265.01159.10277.10006.0546

NM-Carborundum, inhomogeneous mixture, effects 3.0512NM, cavitation sensitivity

NM, CJ properties, oxygen balanceNM, conductivity profiles, C precipitationNM, cylinder test results

NM, dark wave structure, camera records

NM decomposition, diamond-anvil cell

NM, decomposition, Kamlet’s methodNM, decomposition kineticsNM, detonation pressure dataNM, detonation temperature, pyrometerNM, detonation temperature, test setupNM, detonation velocity measurementsNM, diameter-effect parametersNM, diluent effect on detonationNM, DINA, TNT, dithekite, shock initiation

NM, early research

NM, EOS constants

NM, experimental & calculated CJ parametersNM, experimental detonation velocity data

NM, failure diameters, initial temperaturesNM, fa~ltire, rarefaction cooling, 2D modelNM, failure waves, foils, transient wavesNM, free-surface velocity dataNM HE foamsNM HugoniotNM, light emission, estimated shock temperatures

NM, light emitted from reaction zoneNM, liquid diluents effect on propagation

NM, LV-D & HVD in liquid HE, card gap testNM, mixtures, propertiesNM, ntemal/extemal vel., camera record

NM, overdriven shock HugoniotNM performanceNIvVPMMA/Al, cellular structure of detonation

7.0373

8.05474,05004.0005

5.0170

9.1019

6.00966.00957.05318.05588.05695.004 I6.06477,0583

30469

3.0789

7.0619

6.0713

5.00745.0102

6.04053.07917.05379.13649.03795.0153

4.06046.0133

4.04127,0584

3.0472

9.04439.04786.0124

67

B. Topic Phrase Index (Continued).


NM,NM,

NM,NM,

NM,NM,NM,NM,NM,NM,NM,

polarization & relaxation signals

predicted times, reaction zones, E, P, Vradiance and detonation temperaturereaction pathways in shock initiationsensitivity cavitation effectsensitized, SDTshock compression through inert, DDTshock interaction with discontinuitiesshock sensitivity, lattice densityshock wave growth modesshocked, vibrational spectroscopy

6.0144

4.03957.0762

8.08557.03749.00393.08134.0386

9.02356.0047

9.0172NM/Si02 velocity/diameter relation, model 7.0589NM, stable low-velocity detonation wave 7.0575NM, strong detonation waves 8.0425NM, temperature & diameter effects 2.0454NM, temperature behind shock, Raman scat. 7.1010NM, temperature effects, gap test 5.0237NM, thermal decomposition at P= 10-50 kbar 5.0331NM, threshold velocity, bum rate 6.0119NM, time-resolved emission 7.0993NM-TNM mixtures, low & high-velocity waves 4.0126NM/TNM mixtures, detonation wave temperatures 7.0768NM., unimolectdar decompositionNM, velocity-diameter relation, modelNM, vibrational spectroscopyNM-PMMA-GMB, microballoon concentrationNO, initiation & detonationNOl, molecular excitation energies

NO: deformation modes, TATBNOt groups, role in molecular excitation

NOL & MRL SSGTNOL gap test, modelNOL large-scale card gap testNOL large-scale gap test, modified (LASI)NOL large-scale gap test, modified (MGT)NOL large-scale gap testNOL shock sensitivity test, shock pressureNOL small-scale gap test (SSGT) replacement

NOL SSGT, decreased sensitivity at lower TMDNONA, initiation threshold, high tONONA, shock Hugoniots & initiation threshold

Nondetormtive explosions, confined chargesNondetonative explosions, H6 & PBXW- 109

Nondetomative explosions, venting effect, modelNondimensional profiles, nonideal detonationNonequilibrium, diffusion-controlled reactions

Nonequilibrium flow, wave propagation

Nonequilibrium in shock compression zone

Nonequilibrium molecular dynamic method

Nonideal 1D detonation waves, model

Nonideal behavior, HMX/AP/A1 propellant

68

8.08287.05899.01809.09259.13357.0100

9.0153

9.01729.00988.02337,02657.02857.03089.00833.05847.0924

9.00986.00445.02197.0247

7.0308

7.0175

8.10299.07437.0795

7.0789

8.0680

8.10257.0620

Nonideal detonation, ANFO mixtures

Nonideal detonation, C.E.E. 2D model

Nonideal detonation, emulsion, modelNonideal detonation, kinetic lattice modelNonideal detonation, lateral expansionNonideal explosive, AN, D & PNonideal explosives, diameter effectNonideal explosives, reaction ratesNonlaminar flow effects in gases

Nonreactive rarefaction fan solutionNonstationary detonation waves in gasesNonsteady behavior and rate, EOS model

Nonsteady detonation, reviewNonsteady effects, liquids & single crystals

Nonsteady flow in a detonatorNonsteady state detonation velocity, microwaveNova model, gun interior ballistics codeNozzle concept, long cylindrical chargesNozzle theory (H. Jones), diameter effectNozzle theory, ID modei, slurry

Nozzle theory, reaction rate of TNT/NAN03NQ, 3D hydrodynamic hot-spot model

NQ/AP composites, detonation parametersNQ, bond lengths, crystallographic dataNQ, CJ properties, oxygen balanceNQ, direct-contact sensitivity testNQ, electron density distribution analysisNQ, eutectic composite explosivesNQ, gas pockets in low-velocity detonation

NQ, performance

NQ, retarded detonation, tricks (chicanery)NQ, sympathetic detonation of AP

NSWC impact machine, hazard responseNTO/’binder formulationsNTO, isentropic expansionNTO, molecular modelNTO, performance, QNTO, properties’& perfomnance

NTO/RDX/binder formulationsNTO, theoretical and thermochemical dataNuclear weapon simulation with TNT testNucleation of hot spots

Numerical codes, 1D & 2D, along with testsNumerical codes, 2D, unsteady flow

Numerical modeling, DDTNumerical modeling of reactive mediaNumerical simulation, DDT, TS 3659 propellant

NWC porous-bed codeO-nitroanisole, shock-induced electric signal

O-NOz, time-to explosion

OB ,M, oxidants in sensitivity relationships

3.0309

7,0695

8.10696.03444.01079.05609.01979,01974.0070

8.1027I .00457.0703

3.0784

3.07919.08162.01517.0850

2.07593.03428.01682.0519

8.00446.01788.08418.05474.04048.08397.0803

2.0584

9.0478

6.02266.01739,12439.10019.04899.11859.0478910019.1001

9.0489

8.04189.0050

4.05194.05279.o~59

9.02509.0329

9.03635,03879 02?s

3.067 \

.

.


Subject Sy.Pg Subject sy,Pq

..

Oblique detonation wave interaction at interfaces

Oblique detonation waves interacting, iron

Oblique impact, large chargesOblique impact, metal plate on explosive

Oblique shock, detonation wave perpendicularOblique shock, initiation of pelletsOctol-A, -B, thermal initiation & growthOctol-A, growth of reactionOctol, chemical decomposition model

Octol, cylinder test resultsOctol, density, shock & particle velocitiesOctol, diameter-effect parameters

Octol, Hugoniot

Octol, jet temperatures, IR radiometerOctol, low-order explosions after impact

Octol, low-pressure point on isentropeOctol, nondetonative explosive

Octol, Plexiglas monitor, shock velocityOctol, thin flyer-plate impactOctorane 86A, low-velocity projectile impactODTX testOMA, optical multichannel analyzerOne-dimensional steady detonation wave modelOne-dimensional time-to-explosion (ODTX) testOne-fluid Van der Waal’s mixture modelOnionskin experimentONTA, use to prepare an IHE

Open-camera detonation light records, NMOptical fiber gauges for DDr experiments

Optical fiber/photocell DDT tubeOptical properties of detonation waves

Optical region, homogeneous HE cylindersOptical system, VISAR/emission measured

Optical technique, detonation front tempOptics, detonation wave generatorsOptics, multiframe microscope photographyOpto-electronic plastic optical fiberORA 86, properties, detonation velocity

Orvis velocimeterOrvis interferometer, TNT & RDX

Oscillograms, inert-HE velocity, u(t)Oscillograms, shock-induced polarizationOscillograph vs light absorption, shock front

Oscilloscope records, drop weight test outputOscilloscope traces, shaped-charge temperatureOTTO, liquid HE, characterization

overdrive and Mach reflection of wavesOverdriven Comp B Hugoniot

Overdriven detonations, setup for NMOverdriven explosives, shocked statesOverdriven pressure decreases to CJ point

9.0842

4.0153

5.02964.03816.06023.07915.02806.02907.0056

4.00054.0245

6.0647

9,0379

6.06916.03283.03897.0248

5.00239.00669.10479.10709.10195.00247.00567.06469.07309.10085.0116

9.0259

7.01205.0513

5.0515

8.00177.07595.05132.01728.04659.10087.1084

9.00506.0030

6.01452.0225

6.02926.66966.04677.07969.03798.0425

5.05331.0056

Overdriven shock Hugoniots, four HEs

Oxidant balance, impact height, sensitivityOxidant balance, OB,@, decomposition

Oxidant balance, OB explosive, particle sizesOxidant balance, plasma, detonation velocityOxidant balance, solid carbon (CS EOS)Oxygen balance, impact sensitivityOxygen-balanced, -deficient CHNO explosivesOxygen ratio effect on detonation frontOxynitrotriazole, using to prepare an IHE

P 2100 B, ballistic classificationP-v diagram for steady, 1D ozone detonation

P-t data for compressive fronts

P-uP measurement methods for HE productsP2~ detonation criterion, derivation

Pi vs pressure sensitivity cutve

Pallet fires, single and multiple shells

PANDA, an HE EOS codeParallel probes, conductivity, SPHF glass platesParamagnetic decomposition products, spectraParamagnetic resonance products in HEParameter effects, ideal detonation stateParameters for CJ, ignition & growth calculationPartially reacted HE, Hugoniot statesParticle & gradient with moving gridParticle impact on PETN & RDX crystalsParticle shape, shock sensitivity effectParticle velocities, camera record, measured

Particle velocities, free-surface, difference

Particle velocities, impacted PMMAParticle velocities, magnetic probe

Particle velocities, test & modelParticIe velocities, TNT, Lagrange gaugeParticle velocities, vs distance, modelParticle velocities, vs time, acceptor HEsParticle velocity, distance diagrams, DDTParticle velocity, EM gauge, in situ

Particle ‘velocity, gauge system, newParticle velocity, histories, HNSParticle velocity histories in EAKParticle velocity, stress calculation, gaugesParticle-breakup model for DDTParticle-size characteristics of UK TATB

Particle-size effects, 1- & 2-component HEParticle-size effects, ANFOParticle-size effects, AP/NQParticle-size effects, cobalt amine azidesParticle-size effects, critical diameterParticle-size effects, D and curvatureParticle-size effects, DDTParticle-size effects, DDT

9.0443

3.067 i

6.03128.10113.01928.08093.06936.05487.0768

9.10088.06264.0069

9.0354

9.03798.11199.1451

8.0214

9.04433.01568.07349.09878.07749.01338.09434.0527

9.12769.00833.0420

6.0637

5.05926.0637

7.10346.07876.03555.04846.02397.1062

8.04478.00199.0089

5.04279.0329

9.01232.04783.03126.01753.00508.09029.00187.01077.0119

69



Particle-sizePttrtlcie-sizeParticle-size

Particle-sizeParticle-sizeParticle-sizeParticle-sizeParticle-size

Particle-sizeParticle-size

Particle-size

effects, DDT

effects, detonation velocityeffects, detonation waves

effects, EA eutecticeffects, HMX/waxeffects hot-spot temperatureeffects, initiation, HMXeffects, negative OB explosives

effects, oxidizers,propellantseffects, PETN, RDX, & tetryl

effects, run time vs pressureParticle-size effects, sensitivity, RDX

Par[lcle-size effects, sensitivity, RDXParticle-size effects, TATB inititibility

Pttrticle-size effects, tetryl, DDT study

Particle-velocity histories, PBH-9DParticle-velocity profiles, LX- 17

Paterson EOS, long-range molecular forcesPath-1ine method, MIV gauge, PBX 9502Pb-HMX-PBX 9404, overdriven, shocked statesPBH-9D, reaction ratesPBX 0280, ignition thresholdPBX ,9010, PBX 9011 cylinder test results

PBX 9011, low-velocity impact sensitivityPBX 9205, underwater spherical explosionsPBX 9404, 1D pressure-shear loadingPBX 9404, 2D model, initiation and growth

PBX 9404, 2DE model, wave propagation,comersPBX 9404, 3-Term ignition and growth modelPBX 9404, aquarium test data, d = 7.2 cmPBX 9404, bare & covered, shockedPBX 9404, calculated reaction zonePBX 9404, camera record, impact to initiationPBX 9404, central detonation, air & waterPBX 9404, chemical decomposition models

PBX 9404, CJ adiabats, Hugoniots

PBX 9404, cylinder test results

PBX 9404, DAGMAR vs short-shock data

PBX 9404, detonation criterion studyPBX 9404, detonation pressure dataPBX 9404, detonation threshold parametersPBX 9404, detonation wave interactionsPBX 9404, diameter-effect parametersPBX 9404, driver of beryllium

PBX 9404/dural, free-surface velocityPBX 94(I4,PBX 9404,PBX 9404,

PBX 9404,

PBX 9404,

PBX 9404,

70

electron beam, initiationEOS above CJ pressureEOS constants

EOS for hot and cold solids

tlyer plate, critical surface area

gauge record analysis, ejects

7.0166

3,0791

8.10477.0549

4.03990

5.02289.00258.1011

3.08255.0259

3.05158.0902

9.0018

8.10476.0426

9.01429.01123.0722

9.06835.05339.01429.14604.0005

4.0478

5.05998.02747.0488

6.04068.09515.00647.03259.06933.0426

6.05287.0056

8.0503

4.0005

8.0107

6.00787.05316.00727.06696.06476.06027.05367.00508.05877.0407

8.0038

7.0316

7.0883

PBX 9404, growth of reaction, skid test 6.0290PBX 9404, heat of detonation Q, D, PCJ 3,0744PBX 9404, hot-spot initiation model 7.0394

PBX 9404, Hugoniot curves & sound ~~elocity 4.0235PBX 9404, Hugoniot data for unreacted HE 5.0251PBX 9404, Hugoniot, shock around CJ point 9.0379PBX 9404, 12C photo, line detonation, EBWS 6.0666PBX 9404, impact response, model & tests 7.0273PBX 9404, initiation threshold, high temp 6.0044PBX 9404, low-order explosions after impact 6.0328

PBX 9404, low-velocity impact sensitivity 4.0478

PBX 9404, model application to shock initiation 9.0604

PBX 9404, oblique shocks, perpendicular drive 6.0602

PBX 9404, overdriven shock Hugoniot 9.0443PBX 9404, particle velocities, magnetic probe 6.0637

PBX 9404 performance, Q, Cu cylinder test 9.0478

PBX 9404, physical parameters 7.0593

PBX 9404, Plexiglas monitor, shock velocity 5.0023PBX 9404, polytropic, JWL, constant-~ EOSS 6.0566PBX 9404, Pop plot, 1D & 2D models 8.0059PBX 9404, Pop plots, highest-density model 7.0237PBX 9404, postdetonation behavior theory 8.0501PBX 9404, pressure effects on initiation 5.0321PBX 9404, pulse duration sensitizing effect 5.0191PBX 9404, radius-of-curvature effects 4,0088PBX 9404, reaction zone structure 9.0670PBX 9404, Ree’s prediction vs data 8.0513

PBX 9404, shock desensitization 8.1057PBX 9404, shock front temperature 7.1005PBX 9404, shock Hugoniots & initiation threshold 5.0219PBX 9404, shock wave growth modes, initiationPBX 9404, shocked, IR emission measurementsPBX 9404, shocked, pressures, model and test

PBX 9404, shocked quartz gauges, upstrettmPBX 9404, short-duration shock initiationPBX 9404, short-pulse shock initiation

PBX 9404, short-duration-shock responsePBX 9404, sustaikd-shock histories

PBX 9404,PBX 9404,PBX 9404,PBX 9404,PBX 9404,PBX 9404,PBX 9404,PBX 9407,PBX 9407,

PBX 950

PBX 950

PBX 950

PBX 950

sustained-shock responsethermal initiation and growthtime-resolved ,conductivity test

underwater shock-to-burn testsvelocity-diameter predictive modelwave surface curvature effectswaveforms, microwave record

exploding-foil shock set]s~livitysustained 1D shock initlauonaquarium test records

critical thickness

detonation parameters for EED.properties, binder effect

6.00477.09938.0931

5.04354.03737,0859

9,0604

8.0104

9.06045.()~80

9.03964,04897.05896.03798.04917.09289.1224

8.0981

9.0396

9,03s8

9,1014

.

●

.

IB. Topic Phrase Index (Continued) I

Subject Sy.Pg Subject sy.Pg I

PBX 9501, time-resolved conductivity, detonating 9.0396

PBX 9501, time-resolved conductivity testPBX 9502, composition, densitiesPBX 9502, confinement ‘effect on failurePBX 9502, comer-turning dataPBX 9502, desensitization calculations

PBX 9502, detonation pressure data

PBX 9502, detonation reaction zone study

PBX 9502, detonation reaction zone studyPBX 9502, electron beam initiation

PBX 9502, Hugoniot, shock around CJ point

PBX 9502, MIV gauge experimentsPBX 9502, properties, binder effectPBX 9502, reaction-zone structurePBX 9502 performance, Q, Cu cylinder testPBX 9502, tensile propertiesPBX 9502, triple shock-wave interactionPBX 9502, Um, magnetic probePBX, behavior during drop weight impactPBX, castPBX, cast-cured, behavioral modelPBX, cast-cured, effects of inert binders

. PBX, cast-cured, wedge test modeling

PBX properties, effect of binder concentrationPBX shock sensitivity, RDX crystal shape effect.PBX-N5, thin flyer-plate impactPBXN-5 sensitivity crossover, pressure

PBXS, fracture strengthPBX W- 109, burning & detonation, gap testPBXW-113, ignition thresholdPBXW-115, detonation propagationPBXW- 115, failure thickness

PBXW-115, time-resolved HE conductivity testPE4, sensitivity and explosivenessPeak pressure, and particle velocities, Al & CuPeak pressure, effect, critical energy

Peak pressure, positive impulse, spheres

Peak pressure, transmitted by foams

Pentafluorothio group, effect on HE propertiesPentanex, bubble energy, underwater expansionPentolite, artificial viscosity calculationPentolite, case effect on airblastPentolite, conducting zone, electrical effectPentolite, deflagration waves, DDT studyPentolite, density & velocitiesPentolite, density, D, cd, experimental PPentolite, detonation velocitiesPentolite, EMF generated by conduction zone

Pentolite, growth to detonation, interferometerPentolite, high-density gas, electrode, x rayPentolite, high-vacuum detonation

9.03967.0567

8.03727.0630

8.00477.0531

8.0123

8.0123

7.0052

9.03799.06839.10149.06579.04788.06377.06697.0538

8.06359.00187.05607.0560

9.12179.1014

9.00839.00666.00749.08867.0308

9.14609.08069.0396

9.03968.02654.0284

6.00126.0533

4.0273

9.11626.05465.05976.07773.0120

6.02414.02453.03771.00143.01164.0584

3.01365,0561

Pentolite, Hugoniot, shock around CJ point 9.0379Pentolite, inert monitor, shock velocity 5.0023Pentolite, initiation by air shock, delay time 3.0790Pentolite, lateral shock pressure tests 4.0095Pentolite, measured detonation pressure 5.0065Pentolite, shocked sympathetic detonation 3.0521Pentolite, shocked, thermal film record 7.0974Pentolite, slurry, contact film record 3.0018Pentolite, spherical explosions in water 6.0570

Pentolite, spherical shocks in water, center-initiated 3.0790Pentolite, underwater shock-wave performrmce

Pentolite, underwater shock-to-bum testsPentolite, vs PBX 9404 shock wave data, model

Pentolite, wave curvature vs charge lengthPentolite, wax-gap testPercus Yevick (PY) EOS, QUATUOR codePercus Yevick, PY, EOS, dense gaseous HEs

Perfect gas, shock polars, deflection anglePerfluorinated alkylamines, synthesisPerformance, NQ, TATB, DINGU, NTO, EARPerformance, NTO

Performance parameters, easier predictionPerformance tests, plate dent, bumPerformance, ZOX, zero-oxygen-balance HE

Peripheral detonation, waveguide designPermeability of deformed/fractured materialsPermeability parametersPerpendicular explosive drive, oblique shocksPerspex mousetraps, shock to detonationPerspex tubes, bum velocity measurementsPerturbation methods in detonation physicsPerturbation on inner surface of shell, 2DL

PETN, 2D simulation of CHNO chainPETN, 3D hydrodynamic hot-spot modelPETN, adiabatic elastic moduli, single crystalPETN/benzoyl peroxide decomposition

PETN, bubble energy, underwater expansion

PETN, bum rate, sensitiveness, Q, m x Q

PETN, calculated & test detonation velocities, PC,PETN, calculated vs test CJ pressure & velocltiei

PETN, chemistry, free expansion of HE productsPETN, CJ point, CJ isentrope, error ‘%.

PETN, CJ properties, oxygen balancePETN, CJ properties vs initial densityPETN, contact film, framing-camera studyPETN, convective bum at higher pressuresPETN, critical length vs critical velocityPETN, cylinder test resultsPETN, DDT study, convective bum, LVDPETN, deflagration before DDTPETN, detonation flame analysis

.4.00274.0489 I6.0528

2.05061.0023

8.07649.0933

5.01297.0941

9.04789.10017.0952

8.03539.0995

1.00319.03639,0280

6.06028.04473.0083 I6.03524.03167.0784

8.00446.03967.0027

6.0546

2.0651

2.04185.05039.09537.07098.05478.05533.00103.00774.04324.0005 I6.0250

1.00602.0572

71

IB. Topic Phrase Index (Continued)


PETN, detonation heat, detonation calorimeterPETN, detonation products, real-time analysis

PETN, detonation temperature, pyrometerPETN. detonation temperature measurementPETN, detonation velocities (30-p,m size)

PETN, detonation velocity, electric probePETN, detonation velocity vs density (D vs p)PETN, dislocations, shear bands

PETN, drop weight impact testPETN, EOS calculations and test resultsPETN, experimental & calculated CJ parametersPETN, experimental vs computed HugoniotsPETN, exploding-foil shock sensitivity

PETN, explosive-etched Cu mesh initiatorPETN, explosive foam

PETN, foamed, low density, characteristics

PETN,PETN,PETN,

PETN,PETN,PETN,PETN,PETN,PETN,PETN,PETN,PETN,

PETN,PETN,

PETN,

PETN,

PETN.

PETN,PETN,PETN,

freeze-out temperatureheat of detonation, con finedlunconfined

high-density shock initiationhigh-vacuum detonationimpact-face pressure, porosity modelimpacted, spectral emissionin methane, low-velocity detonationinitiation threshold, high TOinterstitial gases, sensitivityisothermal linear & volume compressionJCZ state, molecular parameterslaser and shock initiationlaser ignition test

laser initiation

linear memory effect

linear surface regression to 500”C

low-velocity detonation, confined

Mie-Grtineisen EOS, pulsed electron beammolecular electronic structuremonoctystal decomposition vs P

PETN/NaCl, air shocks in air gapPETN, overdriven shock HugoniotPETN, particle-size effect, electrostatic sensitivityPETN, particle-size effects, small-scale gapPETN performance, Q, Cu cylinder testPETN, physical properties

PETN, polymers added, drop-weight impactPETN/polyurethane, detonation properties

PETN/polyurethane, diverging detonationsPETN, Pop plots of highest densityPETN, precursors in detonations

PETN, pressure profiles, Pop plots

PETN, prompt laser initiationPETN, Raman spectraPETN, receptors in gap tests

4.0167

8.07018.05749.0947

1.00144.06169.0443

9.12768.06415.05036.07136.07737.0928

7.0746

9.13645.0047

4.0167

3.07506.0020

5.05597.0443

9.10372.05856.00444.03496.07007.07217.0797

8.04769.1118

3.0047

4.0461

7.0575

5.03517.00659.01728.10729.04439.10765.02599.04787.0033

7.00257.0560

7.04087.02377.0877

6.0022

9.11109.11187.0279

PETN, reflection spectra & ignition threshold 9.1100PETN, retarded detonation, tricks (chicanery) 6.02?6PETN, rubber-bonded sheet explosive 4.0496PETN, sensitivity coefficients for CJ properties 9.0513PETN, shock Hugoniot 3.0570PETN, shock Hugoniots & initiation thresholds 5.0219PETN, shock sensitivity, lattice density 9.0235PETN, shock wave initiation model 6.0371PETN, shocked, pressure vs distance data 5.0225PETN, simulations in hot-spot model 7.0506PETN, single-crystal tests, properties 2.0470PETN, spectroscopic study of detonation 8.0691PETN, sprayed on copper mesh on Mylar 7.0746

PETN, surrounding exploding-wire initiator 1.0012PETN, temperature, measured and calculated 8.0558

PETN, thermal decomposition, p= 10-50 kbar 5.0331PETN, thermal initiation & growth 5.0280PETN, thermodynamic properties, 293 K, O GPa 6.0704PETN, time delay vs lfl, decomposition 3.0067PETN, time-resolved mass spectra, decomposition 9.0162PETN, time-resolved spectromet~ 9.0172PETN, time to explosion 9.0228PETN/TNT, polytropic y, energies, velocity 5.0462PETN, TNT reaction zone lengths 2.0755PETN, underwater detonation, chemistry 9.0626PETN, wedge-brass interface, 1 g/cm3 3.0562Petrin acrylate propellant, sensitivity 3.0830Phase change within shock wave 3.0358Phase changes, C & N 9.0425Phase diagram, carbon 9.0417

Phase diagrams, P-t, carbon 8.0528

Phase separation, diffusion-controlled reactions 9.0743Phase shift vs seal thickness, transit time 6.0399Phase transformation of HNAB, DSC measurement 8.1129Phase transitions, shocke~ Bi, Fe, quartzPhase transitions, types & boundariesPhase velocity of propagation definedPHERMEX, detorfation & shock wavesPHERMEX machine, flow behind wave frontPHERMEX radiographic facility, HE studyPhonon-drag effect, thermoelectricPhonon modes, acoustic & optical

Photodissociation of expansion-cooled C3F,N0

Photocell monitor, light emitted by impact

Photochemical initiation of silver azidePhotoelastic substances, transient stressesPhotography, high-resolution, wave effectsPhotography, high-speed, drop-weight impact

Photography, cavity collapse in emulsion HEsPhotography, fast decomposition in solid HEsPhotolysis & thermolysis of metal azides

4.02484.02494.0258

4.06395.00036.04094.06369.02359.1084

6.0682

2.05471.00316.04149.0886

9.08699.08573.0843

.

.

.

.

.



Photolysis of Ba & K azides

Photolytic initiation

Photomicrographs of emulsion HEs

Photomultiplier & oscilloscope, reaction zonePhotomultiplier detector, density changes

Photomultiplier detector, liquid HE

Photosensitization of HE acceptorsPhysical synthesis, an composite HEPIC (yarticle-in-cell )method,viscosit yaddedPIC method, hydrodynamicsPicramide, radicals in decomposition products

Picric acid, calculated & test DPicric acid, curvature effects on shock wavePicric acid, impact sensitivity, OB IN

Picric acid, mechanical properties

Picric acid, sensitiveness of pressed charges

Picric acid, sensitivity and oxygen balance

Picrylazoles, electronic structurePiezoelectric polymer PVDP gauge measurementsPiezoelectric pressure gauges, casing effectPiezoresistive gauges, gap testsPike equation, air-match point above adiabat

●

Pin array, detonation front velocity, spheresPin-contactor technique, shocked solid HEPin method, measuring detonation velocityPin method, velocity determination, TOAPin signal record, conductivity, TOA signals

Pin switch construction, detonation velocityPin techniques, measuring particle velocityPinned wedge test, HMXPipe bombs, varying ignition methods

Piston impact, low velocity, delayed detonation

Piston impact, porous energetic materials

Piston in fluid, heat from chemical reactionPiston velocity, flow after impact, y = 3Piston velocity, inert against HE slabPiston-driven compaction experiments, simulationPiston-driven DDT in granular HMXPlanar lD explosive-metal model, CJ statesPlanar geometry, detonating LX- 17Planar impact gun test, shock profile detectorPlanar shock initiation, solid HE

2.0530

9.09879.0585

4.06022.0192

7.07597.0938

6.04394.05285.01778.0742

2.04181.00993.06818.0642

2.0643

3.07007.0066

9.15296.07777.0280

4.00536.05224.0373

2.01362.04403.0139

2.01401.01079.00257.02487.0256

8.08824.0502

3.02053.05349.03069.02654.0538

9.01335.03693.0499

.

.

PlanePlane

PlanePlane

PlanePlane

PlanePlanePlane

deton. wave, analysis, sonic point properties 9.0757detonations vs cylindrical, sphericalelastic precursor decay model, cracks

lateral driving testsshock initiation, dilute HE

shock response, critical acceleration

spalling of copper, ID calculationsvs diverging detonation waves

wave generator setup, x ray, PHERMEX

5.00416.0267

8.06257.0448

6.03875.05678.01435.0004

Plane wave generators, Mach phenomenaPlane wave, heat release, flow derivativesPlane wave smear camera record, AP

Plasma in propane, C02, Ne, & in vacuum

Plasmas, dilute, detonation generated, factors

Plastic-bonded-explosives (see PBX)

Plastic-bonded-explosives, binder concentrationPlastic deformation, crystalline solidsPlastic deformation, HE crystalsPlastic deformation, mechanismPlastic deformation, metalsPlastic flow conditions of metalsPlastic flow, initiation of fast decompositionPlastic flow, role in initiationPlastic propellants, gap sensitiveness

Plastic work vs projectile velocity, diameter

Plastisol, card gap sensitivity, propellants

Plastisol-NC propellants, D vs cd

Plastisol-NC propellants, failure diamPlate & cylinder motion, ELA modelPlate acceleration in HE-metal sandwich

Plate dent depth vs detonation velocityPlate dent photos, BTZ & PETN on duralPlate dent results, area behind reaction zonePlate dent test, (small-scale) setupPlate dent test, EA eutectic & othersPlate dent test, HMX/AP/Al propellant

Plate impact, case failure, no ignitionPlate impact test, pressure profilesPlate-push test, disk shot from mortarPlate trajectory, negative pressure regions

Plexiglas, shock compression data

Plug in DDT, HMX, model

PMMA, compression by Iow-ampl. shock wavePMMA, enhanced explosive effect on impactPMMA, Hugoniot for Plexiglas vs APPMMA, Hugoniots, PETN EOS testsPMMA: particle velocity, EMV gauge studiesPMMA, physical properties, shock HugoniotPMh4A, physical propertiesPMMA, propagation speed of release wavesPMMA, shock wave compression, 3-20 kbarPMMA, surface-velocity tests: foil techniquePMMA, u=, initiating PBX 9404, 2DL modelPoint explosion self-similar problem

Polar (Lissajous) plot, push/pull VISARPolar angle vs front & liner velocities

Polar initiation, Comp B on Al spheresPolar species, treatment in EOSPolarization of homogeneous HE, shock inducedPolarization, shock induced in solid HE

8.0431

8.01484.0365

3.0202

3.0184

9.10148.00629.00587.02411.00371.00339.08579.0842

2.06536.0332

3.08254.0099

4.01034.00147.0811

2.07536.04632.07493.07457.05497.0622

7.1048

3.02463.07804.0544

4.0?25

9.0265

4.02147.03084.03635.05075.04144.03267.00335.05894.02224.0215

5.03226.0594

8.04706.0521

6.0521

9,05136.01435.0429

73



Polarization signals, detonation induced 5.0429Polarization signtds, liquid dielectrics 5.0399Polarization test setup, dielectrics 5.0388Polycarbonate (PC), binder effects, properties 7.0025Polyester, physical effects 7.0025Polyethylene, shock-induced electrical signal 5.0387Polymer effect on drop-weight results 7.0024Polymorphous transformation effect on detonation 9.0766Polynitroaliphatic explosives, sensitivityPolynitroaliphatic explosives, sensitivityPolynitroaromatic compounds, sensitivityPolynitrostilbenes, sensitivity and OB1~

Polypropylene binder, physical properties

Polysulfone binder, physical propertiesPolysulfone coating, decreased sensitivity

Polysulfone HugoniotPolysulfone SIP gauge for flying-plate detonatorsPolytropic EOS, changes, shock pulse in waterPolytropic EOS, shock motion of a linerPolytropic y from [P@2/Pc,]- 1Polyvinylidene, PVDF

Pop plot, Comp B, PBX 9404, TATBPop plot, EAKs vs Comp B, tetryl, TNT, PBXSPop plot, low-density TATBPop plot, PETN, high densityPop plot, sensitized NMPop plot, shock wave & initiation dataPop plot, shock initiation behaviorPop plot, XDT, three models, PBX 9404Pop plots, particle size effectsPore collapse and compression modelPore collapse by shock wavePore collapse from shock loadingPore radial motionPore surface heating by viscous flowPorosi[ydependent shear modulusPorosity effect, low-density charges, Andreev

Porosity effect, pressed HE, bum ratePorosity effect, strong shocks, EOS (talc)

Porosity vs ignition energy, Hugoniot curvePorous bed burning, DDT model

Porous bed compaction, inert materials

Porous bed compaction, HMX strain rate

3.06726.0312

3.06803.0684

7.0033

7.00258.02579.08229.08226.05613.02755.00569.15297.0487

8.10087.0386

7.02379.00394.02378.09458.09329.00187.0523

9.05938.00269.09067.04357.0201

3.07947.09043.0396

4.0181

7.0234

7.0843

8.0654Porous bed, HM-X, response, deflagration & shock 9.0280Porous bed materials, Th4D, average particle size 8.0883Porous beds, DDT 9.0259Porous beds, dynamic compression, ball propellant 9.0341Porous beds of HE, compressive reaction 8.0881Porous charge, detonating precursors 7.0877Porous charge, HMX regression rates 7.0173Porous charge, shock-induced heating 7.0523

74

Porous nitramines, DDTPorous, nonreactive materials, responsePorous solid, shock propagationPorous solids, thermochemical model, shock

Postdetonation kinetics, diffusion coefficientPostpeak ignition (PPI) traces, gap testPotassium picrate, bum rate, sensitivenessPotential energy calculations, Gaussian 86 codePotential energy surfaces, bond scissionPowder morphology effect, HNS

Powder train time-delay element

Prandtl-Meyer expansion, “simple” wave flowPrandtl-Meyer fan, explosive edge calculationPrandtl-Meyer flow behind detonation wavePrandtl-Meyer singularity, steady detonationPrecompressing charges, quenching air shockPrecompression effects, flyersPrecompression effects, liquid & solid HEPrecompression effects, TNT & Comp BPrecursor air shock, piston effect of HEPrecursor, detonating porous HEPrecursor, shock desensitization

Precursor wave detector, streak camera, prismPrecursor wave, fluid & air cavitation effect

Precursor wave, water-control testsPredetonation column length, compaction effectPredetonation column length (PCL)Predetonation transient wavesPredicting detonation parameters with VL W EOSPredicting hazard response, energetic mat., impactPredicting performance parameters, simplifiedPredicting ideal detonation velocitiesPredicting threshold for jet initiationPreheating effect on detonating lead azidePreignition reaction zonePremature ignition of HE

Premature initiationPremature simulatorPreshocked PBX 9404 and Comp B-3

Preshocking solid HE to make it insensitive

Pressed-booster explosives, shock sensitivity

Pressing HE, vacuum-molding chargesPressure & density in shocked solids, modelPressure at detonation front, baratolPressure at impact vs temperature, PBX 9404Pressure contours, shocked LX- 17, modelPressure cycling, effect on burning ratePressure deflagration rate, closed vesselPressure deflection curves, flow diagrams

Pressure dependence on loading density

9.02596.07664.02589.11999.11937.09162.065 I

9.10278.08?77.0938

1.0032

3.05784.0016

3.07876.0356

3.07987.09385.00677.00038.10697.08777.0352

4.05734.0117

5.00816.04337.01077.02489.04359.12437.0952

9.05139.14042.05699.01629.14609.1480

9.1451

8.10573.0785

9.0098

2.01234.05559.13787.10077.04919.13106.01954.0382

6.0714

Pressure desensitization, water-based emulsion HEs 9.0585

.

.

.

.

.

.



Pressure, detonation, shock, impact, aquarium

Pressure-distance curves: Q, LAX, analytic

Pressure effect, bonds, reaction, modelPressure effect, electronic structurePressure effect, HE decompositionPressure effect, initiating, NM & TNT, in NG

Pressure effect, low-velocity detonation

Pressure effect, molecular decomposition

Pressure effect, octol, hot wire, hot platePressure entering receptor, model

Pressure evolution, transient zonePressure gauge (shock), carbon resistorPressure gradients across wave frontPressure histories, shocked metals, wave forms

Pressure measurement by manganin wire gaugePressure-particle velocity data, HBX- 1Pressure-particle velocity fits, HMX/TNTPressure-particle velocity of HE products

Pressure peak & time behind the shock, decayPressure probe record, NOL gap test

Pressure profile, detonating solid explosivePressure profile, detonation wave, NM

●

o Pressure profile, detonation wave, P vs xPressure profile, detonation wave vs Al platePressure profile, for reaction zones, solid HEPressure profile, reaction zone in Al platePressure pulses, x-t plotsPressure ratios at critical j3, calculatedPressure rise in confined chargesPressure-shear loading (lD) of PBX 9404

Pressure signatures, calculated, underwaterPressure-specific VOI, supracompressed detonationPressure spectroscopic studies, NO

Pressure-time profiles, inhomogeneitiesPressure-time profiles, low-order initiationPressure transducer, sulfur, calibration

Pressure-velocity slopes, phase transitions

Pressure, vicinal, Pv, far from bubblePressure vs Eulerian position s, time ~Pressure vs excess transit time, solid HEPressure vs particle velocity, isentrope

.

Pressure vs pulse length, initiation criteriaPressure vs time, acceptor HEsPressure vs UP, overdriven Comp BPressure-wave reflection effect on bumPressure-wave velocity in maplePressurized HE, measured D

Prestressing shock, metal-HE interface

Primacord, DPrimacord, exploding-wire initiators

Primacord, lateral shock pressure tests

3.0357

3.06197.0093

8.08275.0331

5.0156

2.0585

8.0835

5.02834.0555

8.01435.00472.0514

4.02716.06255.05284.0061

9.03793.0795

3.0590

3.0241

6.0138

2.03272.03722.03454.05256.01066.05786.02118.02746.0556

9.0670

8.07166,0341

6.03253.02414.0256

6.01203,05514.02373.03877.0429

5.04854,00517.0186

1.00315.00734,0383

1.0014

1.00094.0095

Primacord, P-t profilesPrimakof similarity solution, shocked inert

Primary HEs, physical & thermodynamic dataPrimers, initiating power, numerical quantityPrism test, confinement effect on failure

Probe, coaxial, optical and electrical

Probe, conductivity, effects & suitabilityProbe, shape changes, model & tests

Probit tests, card gap tests

Proceedings indexes, Det. Symposia, 1951-1985

Products in preignition reaction zoneProducts of detonation for SF~ model compoundProfile streak technique, wave profiles

Profilometer study of HE fracture surfacesProgressive reconsolidation mode, DDTProjectile attack test, sensitiveness testingProjectile impact, model

Projectile impact, modelProjectile impact, model

Projectile impact, propellants

Projectile impact, sensitivity, ammunition

Projectile-impact shock initiation model

Projectile impact, small-caliber, composite HEProjectile impact, testsProjectile impact, tests, RDX particle sizeProjectile, spherical, impact on HEsProjectile velocity, barrier lengthProjectile velocity, three laser beamsPropagating deflagration, confinement effectPropagating detonation front in TATB

Propagating detonation model, munitionsPropagating detonation threshold

Propagating fast reaction, lead azide crystals

Propagating shock & detonation wavesPropagation of detonation from impact regionPropagation rate, impact machine, photographs

Propagation rate, TNT, air gap effectPropagation test vs gap test resultsPropagation theory, Kirkwood/BrinkleyPropane, detonation velocity measurementsPropane-impregnated HE, detonation tempsPropane isomers, failure diameter & sensitivityPropellant, acceleration simulatorPropellant burn, camera & x rays, shotgunPropellant bum, D & E, propertiesPropellant bum, delayed detonation in granularPropellant bum, diam effect, reaction zone

Propellant bum, dual thresholds in gap testPropellant bum, explosiveness, RARDE bum tube

Propellant bum, failure diam predictionPropellant bum, gap sensitiveness

3.0317

4.0510

9.11002.06028.0372

8.0089

2.0443

4.05977.0265

9.1543

9.01629.11628.03309.09187.01683.06607.0175

7.03257.0343

9.10526.0682

8.0307

9.10477.03168.09079.14274.04337.03006.0204

6.07627.1055

5.02075.0301

4.00799.07983.0010

8.04092.06561.01075.00442.01665.00897,09157.030?8.02857,02564.0097

7.02677.1040

4.0102

2.0653

.75



Propellant bum, high-velocity impact response 8.0284Propellant bum, large-scale initiation study 7.0887Propellant bum, nonidetd detonation, HMX/AP/Al 7.0620Propellant bum, porous-bed DDT study vs model 6.0258Propellant bum, reflection & recirculation 7.0186Propellant burn, sensitivity, card gap test 3.0822Propellant burn, shocked & desensitized, hot spots 3.0796

Propellant bum, temperature determines rate 2.0741Propellant failure diam, estimated, small-scale test 9.0701Propellants, booster rocket, characterization 9.1060Propellants, composite, response to shock loading 9.0879Propellrmts, gun, detonation characteristics 9.0537Propellants, projectile impact 9.1052Propyl nitrate, threshold velocity, bum rate 6.0119Prospects for composite HE 9.0554PSF, polysulfone film gauge 9.0822PTFE insulator, manganin gauge, pressure 6.0626Pulse duration effect, Comp B, B-3, PBX 9404 5.0191Pulsed-laser-excited Raman spectra, TATB 9.0153PVDF gauge charge vs stress 9.1529PVDF gauge, detonation response measurements 9.1529Pyridine, effects on DDT,ammonium perchlorate 7.0153Pyrometer, detonation product temperature 8.0567Pyrometer, four-color, brightness in NM-TNM 7.0768Pyrometer, four-color, NM, TNT, PETN, RDX, ... 8.0558Pyrometer, measurement of detonation temperature 9.0939

Pyrometer, two-color optical fiber -Q, heat of detonationQ method, calculation, underwater flowQ method, model, confined deflagrationQ-switched laser pulse initiation

Quartz, elastic precursor & shock wave photosQuartz gauge, front-back setup, PETNQuartz gauge, records, HNAB Hugoniot

Quartz gauge, Sandia, construction & testing

Quartz gauge, technique for impact testsQuartz gauge, thick, shocked PMMA, records

Quartz gauge, upstream of shocked HEQuasi-sonic discontinuity, CJ detonation

Qunsl-static compaction of inertsQuasi-static stress-strain curves: Al, steelQuasi-steady reaction wave

QUATUOR code, detonation thermochemistry

QUATUOR thermochemical code, gaseous HEsRadial flow in drop-weight-impact experimentsRadial velocities, collapsing cavitiesRadiance signals, HE-loaded copper plates

Radiances, NG, NM, DEGDN, EN, 2-NERadiation effect on propellantsRadiation measurements in reaction zoneRadiation signal during detonation

76

8.05679.04794.00333.06066.06124.0569

6.00217.04195.03695.03694.0222

5.04357.06357.08434.02989.0219

8.07629.09339.08868.00786.06937.0764

1.00324.06022.0144

Radiative vs hot-gas ignitionRadiographs, detonation zoneRadiography of impacted HEs

Radiography, PHERMEX, rarefaction wavesRadiolysis-stimulated detonationRadiometer, 2-color infrared, shaped charge

Radiometnc experiments, RDX particle size

Radius-of-curvature effect on detonation velocity

Radius-time history, Cu cylinders, Comp BRaman measurements, reaction zone lengthRaman scattering temperature, shock waveRaman spectra of PETN

Raman spectra, PETN and HMX, single pulsesRaman spectra, shock-compressed TATBRaman spectra, shocked RDX, PETN crystalsRaman spectra, solid nitric oxideRaman spectrometry, ultra fastRaman spectroscopy, coherent anti-StokesRaman spectroscopy, experimental setupRaman spectroscopy, laser, ignition zoneRamp-induced compression, propellant initiationRamp wave risetime effect on run-up distanceRamp waves, PBX 9404

Random choice hydrodynamics code, RCMRandom choice method, detonation simulationRandom choice method, diverging detonationRankine-Hugoniot condition, discontinuitiesRankine-Hugoniot condition, vector in equationsRankine-Hugoniot condition, pressure modelRankine-Hugoniot curve in mixed phaseRankine-Hugoniot equations, P,v, fluid

Rankine-Hugoniot equations, reflected shockRankine-Hugoniot equations, lD steady stateRankine-Hugoniot equations, shock compressionRankine-Hugoniot equations, precompression

RARDE burning-tube test, low explosivesRARDE small-scale burning-tube test

RARDE small-s~dle booster cook-off test setupRare faction effect on Mach bridgeRarefaction-overtake model vs initiation dataRarefaction waves in explosive products, x rayRarefaction waves restricting acceleration

Rarefactions from metal-HE interface, AlRaster chronograph, detonation velocityRate of chemical energy release, heterogeneous HERate of expansion & ~ for peak stressesRate parameters, critical diameter & velocityRate stick, 2D, calculatedRate stick, analyzed by difference methodRate stick, assembly, joints effectsRate stick, Comp B, particle size effects

8.04814.0162

9.10194.06429.11316.0691

9.00254.00864.00048.06917,10109.1118

8.06969.01538.0847

8.07199.0172

9.01807.10139.11518.09628.09707.0394

9.07517.0799

9.07432.03172.04266.06044.02522.0219

3.02153.03054.02075.00688.02118.0262

8.11074.01447.0431

5.00143.0579

2.03792.0137

19.01974.04927.05899,0730

3.03346.06422.0480

.

.

.

. I

.

.

.

.



Rate stick, failure radii, 2D model 7.0488

Rate stick geometry, detonation shock dynamics 9.0773

Rate stick, plate dent, unconfined AN composition 7.0806Rate stick, production 2.0120Rate stick, propellant, nonicieal behavior 7.0620Rates of conductivity change 9.0407Rates of energy transfer & reaction 9.0235Rates of reaction, estimates, II? emission 7.0993

Rayl definition, shock impedance of acceptor 2.0633Rayleigh line-Hugoniot, steam condensation 2.0298

RCM, random choice method code 9.0751

RDX/A, deflagration velocity, electric probe 4.0616RDX/A, electric spark initiation tests 3.0706RDX/Al/PBX, sensitivity & performance, SDDT 8.1132RDX/AN/MAN, cyl. tests vs BKW EOS (TIGER) 6.0439

RDX/AP propellant, input parameters 6.0350RDX, axial fuse initiation vs normal booster 4.0156RDX, BKW model and performance data 3.0728RDXlboron, V vs d, reaction kinetics 2.0733RDX, bum rate, sensitiveness, Q, m x Q 2.0651RDX, calculated & test detonation velocities 2.0418RDX, chemical decomposition model 7.0056RDX, chemistry in free expansion of HE products 9.0953RDX, CJ point, theoretical EOS model

. RDX, CJ pressure vs initial densityRDX, CJ properties, oxygen balanceRDX, contact film, fast-burning modeRDX, convective bum at higher pressures

RDX, crystal growth and morphology

RDX crystal shape, effect on shock sensitivityRDX, crystals, fine & coarse, photomicrographsRDX crystals in HTPB PBXSRDX, D (km/s), densityRDX, DDT phenomena, very small diameters

RDX, DDT study, “resonation” waveRDX, decomposition in shock waveRDX, density, cd, D, experimental pressureRDX, detonation temperature measurementRDX, detonation velocity vs densityRDX, diameter effect, reaction zone thicknessRDX, dislocations, shear bandsRDX, dural, u=RDX, electrical initiation

RDX, electron paramagnetic resonanceRDX, EMV particle velocity mess. in detonator

RDX, energy threshold, P-t piotRDX, EOS parameters

RDX, experimental vs computed Hugoniots

RDX, exploding-foil shock sensitivityRDX, Grades A & B, small-scale gap testRDX, high-vacuum detonation

7.07168.05198.05473.00133.00777.0977

9.00838.09049.00838.05147.0107

5.02319.00503.0376

9.09479.04434.0097

9.12762.03363.0088

7.0075

9.08166.01069.0050

6.07737.0928

9.00985.0559

RDX, hot-spot temperatures, model 7,0524

RDX/HTPB binder, diverging detonations 7.0408

RDX, impact sensitivity and OB *W 3.0674

RDX, impact sensitivity & oxygen balance 3.0699RDX, initiation, photomultiplier records 3.0109RDX, initiation threshold, high tO 6.0044RDX, intermediate radical, activation energy 7.0075RDX, JCZ state, molecular parameters 7.0721

RDX, kinetic parameters 7.0075RDX, laser ignition test 8.0476RDX, laser ignition, Raman spectra, ignition zone 9.1151

RDX, laser initiation 9.111sRDX, light emission during initiation 5.0158RDX, linear surface regression to 500”C 4.0461RDX-loaded EBW initiation 4.0452RDX, mechanical properties, drop weight 8.0642RDX, microhardness, deformation, hot spots 7.0976RDX, Mie-GriJneisen EOS, EB heating 5.0352RDX, molecular electronic structure 7.0065RDX, molecular geometry, bond lengths, ab initio 8.0831

RDXINQIA1, detonation products in Ar, vacuumRDX, paramagnetic decomposition productsRDX, particle effects on sensitivityRDX, particle size effect, small-scale gapRDX, particle size effect, cast PBXRDX, particle sizes, rate stick velocitiesRDX performance

RDX/polybutadiene, CX-84 explosiveRDX/polybutadiene, French explosive

RDX, pore collapse parametersRDX, pressure and heat rise effects, modelRDX, products in preignition reaction zoneRDX, RDX, curvature effect on shock waveRDX, RDX/wax, DDT phasesRDX, reaction products, theoretical EOSRDX, retarded detonation, tricks (chicanexy)RDX, rubber-bonded sheet explosiveRDX, skhsitivity, gas compressionRDX, sensitivity with ammonium nitrateRDX, shock Hugoniots & initiation thresholdRDX, single-crystal tests, propertiesRDX, solid, in modified gap testRDX, ‘spectra, under shock and at rest

RDX, steel-confined, DDT studiesRDX, structure and propertiesRDX, temperature, measured and calculated

RDX, thermal decomposition < melting pointRDX, thermal initiation and growthRDX, time-resolved spectrometryRDX/TNETB, desensitization with wax, OB ,WRDXiTNT, additives, bummg and ignitability

9.09628.07349.00185.02598.09022.01319.04788.03617.0316

9.09067.05239,0162

1.00999.02597.07166.02264.04967.00077,0804

5.02192.04707.03107.00737.01397.0546

8.05587.0075

5.0280

9.01723.06889.0251

77



RDXflNT, Al or LiF admixtures, effectsRDXflNT/Al/Wax, electron beam initiation

RDX/TNT/AN, cyl. tests vs BKW EOS ~IGER)RDX/TNT, crystal structure, sensitivenessRDX/TNT, initiation, pressure variationRDX/TNT, kinetic parametersRDX/TNT, kinetics of simulated initiation

RDX/TNT, LASI gap testRDX/TNT, light emitted from reaction zoneRDX/TNT, low-order reactions--reaction zone

RDX/TNT, polysulfone-coating, ignition

RDX/TNT, polytropic exponent y, energiesRDX/TNT, sensitivity and explosiveness

RDX~NT, shock wave to detonation transitionRDX/TNT, simulated accidentRDX/TNT/wax (Comp B), shaped charge

RDX, tungsten flyer, convergent flowRDX, v-D curves, wave shape vs D, kineticsRDX, volume displaced, drop-impacted sampleRDX, wave curvature vs charge lengthRDX/wax/C, detonating centering device

RDX/wax, DDT, porous bed, mechanics/chemistryRDX/wax, DDTRDX/wax, runup distance and gap testRDX/wax, steel confinement, DDT studiesRDX, wedge test with smear camera resultsRDX, x-ray and infrared studies, bondsReact.heat flow models, HMX, TATB, RDX, TNTReactants, product & detonation parametersReaction behavior in condensed phaseReaction buildup in shocked porous explosivesReaction centers, hot spots

Reaction chemistry, nitric oxideReaction communication distance

Reaction degree, AReaction diagram, pressure-temperature, NMReactIon diffusion theory in detonationReaction growth or decay, low-aml. shocksReaction growth processReaction of molten Al with waterReaction phases: granular, binder, gaseousReaction products, condensed HEs, EPRReaction products, shock properties at C-J pointReaction rate accuracy, Lagrange analysis, gauge

Reaction rate law, nitromethane modelingReaction rate model for shocked HEs

Reaction rate parameters, LX- 17Reaction rate theories, D vs d, 3 extant

Reaction rates, electromagnetic gaugesReaction rates, EMM gauge data

Rettctlon rates, Lagrange & in sittl gauges

6.0510

7.00506.0439

3.06668.01437.00758.01967.02914.06044.04628.0253

5.04598.0265

3.0574

8.02117.03527.0826

2.07333.00082.05068.03328.0972

9.03207.03367.01393.05047.07797.0056

8.10059.03638.09267.0435

8.07156,0047

9.01429.10199.11937.09709.12439.06417.03969.09399.03797.04667.0611

9.05939.0112

2.05198.00998.00837.0466

Reaction rates, nonideal explosives

Reaction rates, nozzle, curved front, D head

Reaction rates of PBH-9D

Reaction thresholds, rocket propellantsReaction zone, cast TNTReaction zone, condensed HE, PMT & scopeReaction zone, detonation head of high-P gasReaction zone, effect, steady axial waveReaction zone, estimate from surface velocityReaction zone, HZ-OZ & acetylene-02 mixtures

Reaction zone, heterogeneous explosivesReaction zone, heterogeneous HE, calculatedReaction zone, length

Reaction zone, length, & CJ pressure measuredReaction zone, length, & temperature variance

Reaction zone, length, cd & curvature radius

Reaction zone, length, curved wavefront, DReaction zone, length, effect on curvatureReaction zone, length, TATB formulationsReaction zone, length, TATB, front curvatureReaction zone, length, TATB, HMX, wave curv.Reaction zone, mass spectroscopy of HE

Reaction zone, parameters, analysis & model

Reaction zone, pressure = CJ pressureReaction zone, preventing CJ pressure dataReaction zone, profiles in detonating HEReaction zone, separation-wave front, effectReaction zone, structure, nonideal in gasReaction zone structure of PBX 9502Reaction zone structure, resolvedReaction zone structure, supracompressed HE

Reaction zone, thickness calculationReaction zone, thickness data, curvature test

Reaction zone, width, predicted for NM

Reactions in porous solids, modelReactive cases, airblast effect from HEReactive Eulerian hydrodynamic code, 3DEReactive explosfdn modelReactive flow analysis & modelsReactive flow, Lagrange analysis (RFLA)Reactive flow, mathematical analog

9.0197

2.0522

9.01429.1060

2.03764.06022.07497.06611.00922.01937.0641

9.0693

3.0327

2.0343

1.00532.0424

1.0096

2.05096.06526.06428.0159

9.01627.03623.03964.05267.10296.04144.01079.06579.06709.06704.00964.0090

4.0395

9.11998.02077.06698.02099.12247.0466

7.0448Reactive flow mess., talc., ZrHz-based composites 9.0525Reactive hydrodynamic (2D) calculations 6,0405Reactive model, HNS 9.0209Reactive modeling, wedge test 91217Reactive multiphase mixtures 8.0501Reactive shock waves, model 8.0943Reactive Huygens construction 9.0730Reactive shock model, compaction simulation 9.0306Reactivity of condensed explosives 9.0246

Rearward compressive wave in DDT 90354

.

.

.

.

78.



Ree’s PBX-9404 model vs dataReflectance-change apparatus

Reflected shock, pressures & angles, calculatedReflected shock, rarefaction, x-t plotReflected shock, TATB study and modelReflected wave velocity vs particle velocityReflected waves in overdriven Comp B

Reflected-wire technique, detonation PReflection and rarefaction tests, PBX 9404Reflection-change flash gap test, D, PReflection spectra of PETN, HMX, & HNS

Regression rate, deflagration at >1 kbarRegressive burning rate, pressure effect

Regular reflection at HE-inert interfaces

Reinitiation in a dark wave, propanes

Relative detonation impulses, prediction

Relative sensitivity of HEsRelease & recompression of detonation productsRelease stress-strain path, elastoplasticityRelease wave approximation, polytropic EOSRelease waves in PMMA, propagation speedREOLIT, booster study, critical diam & mass

.Resistivity, electrical effects of detonationResistivity, electrical/magnetic field

. Resistivity, shocked, inhomogeneous solid HE

8.0513

9.0265

5.05874.05408.01382.03774.0049

8.04228.05915.00139.11006.01957.0168

9.0842

5.0097

7.0954

9.1460

9.05064.02903.02755.05894.04353.01203.01123.0505

Resistivity, vs temperature curve, HE at high temps3 .0063Resolved reaction zone structure 9.0670Resolved reactive zone 9.0693Retarded detonation, velocities > bum rates 6.0225Resonation phenomenon, solid explosives 8.0093Resonation, reflection of divergent waves 4.0426Resonation, retarded detonation, schikanes 6.0225Resonation, shock, detonation curves 7.0355Resonation wave effect, positive/negative, DDT 1.0048Reverberation time, spalled & nonspalled areas 6.0486REX-20, liquid HE, characterization 6.0467RGPA, sensitivity and explosiveness 8.0265Richtrneyer-Meshkov instability 9.0869Richtmyer-von Neumann “Q” method 3.0615RICKSHAW, ID unsteady flow model 5.0501RICKSHAW lD unsteady compressible fluid flow 6.0477RICKSHAW model, 1D unsteady fluid dynamics 6.0629

RICKSHAW model, Be elastic precursor wave 5.0470Riemann problem, mesh cell spacing 7.0799Rigidity effect on shock waves in Al & Cu 4.0277Rise time, magnetic diffusion effects 7.1068Risk evaluation, explosives’ sensitivity 6.0272Risk testing, single- & double-base propellant 6.0299RMX- 11-AY, measured detonation pressure 5.0065Rods & slabs, steady-state wave shapes 9.0784Rotating-mirror camera, split charge & wedge 4.0242

t

Rotating-mirror smear camera, UmRotating-mirror streak camera, schematic

Rotter procedure, impact machine techniqueRubber-bonded PETN sheet explosivesRUBY code, CJ isentrope from K-W EOSRUB Y code, other HE performance vs Comp

Run distance vs pressure & time, solid HERun to detonation in TATB, Pop plotsRun to detonation vs jet penetration velocityRunaway burning, TNT, Comp B, RDX modelsRunup distance, HE-wax sensitivity

RX-03-BB, 2D shock modelRX-04, -05, -09 cylinder test results

RX-04-P-1, curvature radius effects

RX-08-EL, burning rate

RX-23, CJ properties, oxygen balances

RX-23-AA, -AB, -AC CJ parameters

RX-23-AA, -AB isentrope behaviorRX-23 -AB, postdetonation propertiesRX-25-BF, EOS & reaction-rate parametersRX-25-BH, EOS & reaction-rate parameters

2,0330

8.01243.06604.04964.0031

B’s 4.00034.0237

8.03809.14047.01757.03367.0488

4.0005-

4.0088

9.1310

8.0547

6.07137.09427.06479.05259.0525

RX-26-AE (HMX/TATB), chemical decomposition 7.0056RX-26-AF (1-IMWTATB), shocked 7.0325RX-26-AF, EOS above CJ pressure 8.0587RX-26-AF, impact at low temperature 9.0798fi-26-AF propagation of detonation from impact 9.0798RX-26-AF, supracompr., reaction zone structure 9.0670RX-26-AY detonic profiles 7.1032RX-3 5-AP, burning rate 9.1310RX-36, HMXfTATB/BTF, cylinder test data 8.1020S-W EOS for underwater shock waves 6.0570Sabot, Al, fragment-caused vulnerability 7.0326Safety certificate testing, sensitiveness 3.0659Sandwich resistance wire wall probe, trace, DDT 4.0618SAP, IDL spherically symmetric bum code 5.0487Sapphire flyer, short-pulse initiation 7.0860

Sapphire window, flyer, vacuum or gas shots 7.0931Seaming electron micrographs, BTX 6.0462Scanning electron micrographs, eutectics 7.0550Schippel effect, stretched-sheet explosives 4.0499Schlieren photog., cavity collapse, emulsion HE 9.0869Schlieren photos, initiation, acetylene-Oz 2.0270Schlieren photos, precursor shock, PETN/NaCl 8.1072Schottky-barner region, contact, model 6.0390Scotchlite photos, casing effect on airblast 6.0782SC W, strong compressive wave from igniter, DDT 9.0354SDT, damaged energetic materials 9.1295SDT/DDT combined model 8.0962SDT in EAK, Lagrange gauge study 9.0089SDT, instrumented shotgun tests 70301SDT, model of reaction rates 90593

79



SDT, NM, sensitized

SDT, Pop plots for four TATB compounds

SDT, porous HE charges in plastic tubes

SDT process, conceptual interpretationSDT, related to DDTSDT, theory, homogeneous HESDT, thin-plate impacts, projectiles, wedgesSDT, threshold, critical initiating pressureSDT transition data, emulsion HESDT, two-phase multicomponent, PBX 9404SE- 1 detonator, modified, BTX studySecondary explosives, nitrated, bond polarities

Secondary HEs, laser initiationSecondary HEs, prompt laser initiation

Self-pressurizing bomb experimentsSelf-sustaining detonation, EAK & EAKLSemiconductor junctions, shock effects

Sensitiveness, bullet testSensitiveness, combustion dataSensitiveness, detonation, HE, testsSensitiveness, energy release rate

Sensitiveness, heat of explosion QSenQtiveness, limit, preshocked receptors

Sensitiveness, tests, explosive propertiesSensitivity analysis, EOS parametersSensitivity and performance data, gap, modelSensitivity, bond polarity effectsSensitivity curve of HE, theoreticalSensitivi~ experiments, PBX, particle size effectSensitivity, impact vs OB ,WSensitivity, mathematical definitionSensitivity, not absolute criterion

Sensitivity of HE, correlation to compression inputSensitivity of HEs to air compression, deformationSensitivity of HEs to ignition in launch environm.

Sensitivity of liquid HE, NM, TNM, etc.Sensitivity relationships, molecular, OB *W

Sensitivity, shock, substituted benzofuroxansSensitivity test,Sensitivity test,Sensitivity test,Sensitivity test,Sensitivity test,Sensitivity test,Sensitivity test,Sensitivity test,Sensitivity test,

burning, gap, 30-lig impactCO1 lasercolliding-ball HE impactdirect contact with shocks

flyer impacts HE on anvilIHE, laboratory scaleimpact, Henkin, wedge, plateimpact, thermal, spark gap

multivariate approachSensitivity testing of HEs,Sensitivity, vs delay times

Sensitization by voidsSensitizer droplets, role in

80

electrostatic

modeling initiation

9.00398.0380

7.0301

9.05937.01399.0219

8.09025.02079.05738.09436.04627.0071

9.11189.11107.0172

8.01165.0403

2.06602.06432.0601

2.0695

2.06433.0176

3.06598.07708.11317.00689.14519.00183.0674

3.0040

1.01099.14519.1460

9.14604.04123.0671

9.05617.05418.04733.00014.04043.04207.09657.08048.03536.02729.1076

3.00609.08579.1351

Sensitizing effect of polymers

Service lead azide vs dextrinated lead azideSetback-shock simulator, base gap effect

Setback simulation, activator testsSetback simulatorSetback simulator, DREVSF$ (pentafluorothio) group HEs, newShape factor in diameter for initiationShaped charge jet initiationShaped charge penetrationShaped charges, ballistic coefficient

Shaped charges, detonation wave frontShaped charges, initiation, Comp B

Shaped charges, initiation, test and modelShaped charges, linear, design & development

Shaped charges, liner collapse, light tracerShaped charges, temperature measurement

Shaped charges, to disrupt and detonateShaped-charge jets, initiation phenomenaSharp shock calculation, spherical shock wave

Sharp shock, Lagrangian artificial viscosity

Shaw-Johnson (SJ) diffusion modelShear band formation, shock loading, Comp BShear band nucleation, granular HEShear bands, TNT-double base propellantShear bands, hot spots in HE crystalsShear bands, RDX, PETNShear bands, thermal modelShear, chemical reaction, fracture resultShear deformation, fragment attack, confined HE

Shear ignition testShear in impact initiation

Shear-initiated ignitionShear mechanism, impact initiation

Shear-related ignition mechanismShear, role in hot-spot generationShear sensitivity test

Shear velocity at ‘thermal explosionShear velocity in di-constituent explosives

7.0024

2.07117.0914

8.10809.1460

9.14809.1162

7.02739.14049.05378.06307.07517.0352

8.0337

9.1385

1.00316.06918.03189.14166.05286.0529

9.0953

8.11198.00359.00039.00589.12767.00368.02467.1048

9.00038.0294

7.01448.11507,1050

7.09709.0003

7.0041

8.1120Sheet explosive, rubber-bonded PETN, RDX, TNT 4.0496Sheet-explosive deflagration donors 9.1322Shell, 2DE cylindrically symmetric code 5.0487Shell HE fillings with defects, simulat. gun launch 9.1480Shielding effects, 1D model 8.1139Shielding effects, sympathetic detonation 7.1059Shielding materials, high vs low impedance 8.1139Shielding, sympathetic detonation, computation 9.1489

Shock & deformation mitigation by shields 9.1489

Shock amplitude: growth & decay c~nditions 6.0379

Shock and detonation wave interactions 7,0669

Shock and laser initiation 7.0797

.

,

●

✎

.

.


Subject Sy.Pg Subject sy.PCl

Shock and shear mechanism, fragment impact

Shock attenuation in Lucite and waterShock behavior of nonreacting porous solids

Shock behavior of reaction products at C-J pointShock breakup by improved shieldingShock compression, solid & porous HEShock desensitization model

Shock desensitization of PBX 9404 & Comp B-3Shock discontinuity zone, chemical actionShock dynamics, Whitham’s theory, divergent det.Shock effect on aromatics and aliphaticsShock energy fluence, short-pulse effectShock-focusing mechanism, hot spotsShockShock

Shock

ShockShock

ShockShock

ShockShock.Shock

front, angle cO/D, 7000 m/s, nonplanarfront, curvature, test setup, PMMA

front, energy, reactivelnonreactive

front, pressure vs marerial thickness

front, velocity by streak camera recordgeneration in deuterium, laser pulseheating, mechanisms ofHugoniot of unreacted explosives

ignition of single crystals, lattice densitiesimpedance & pressure boundaries

Shock-impedance-matching infrared window

. Shock impedance measurements of CJ stateShock impedance mismatch equation, pressureShock-induced bond scissionShock-induced decomp., FOREST FIRE modelShock-induced electrical polarization in HEShock-induced phase transitions

Shock-induced polarization, homogeneous HEShock-induced reaction, IR emission

Shock-induced signals from dielectrics

Shock-induced sympathetic detonation, solid HEShock-induced thermal rise model

.

Shock initiation,Shock initiation,Shock initiation,

Shock initiation,Shock initiation,Shock initiation,Shock initiation,Shock initiation,Shock initiation,Shock initiation,Shock initiation,

Shock initiation,Shock initiation,

Shock initiation,Shock initiation,

Shock initiation,

& detonation failure modeland P2~bum, underwater, solid HEcorrelating resultscritical ‘conditionsdensity function, TATBH-6 & PBXW-109historical workin liquid explosiveslow-density pressings, APLX- 17 vs temperature

mechanismmodel, hot-spot based

model, hot-spot basedmodel, evaluating newNM, hyperveloclty wave

8.11503.05894.0266

9.03798.1139

6.00058.0052

8.10577.07919,07847.07936.00686.03711.00535.0478

4.0584

2.03284.0440

5.03618.00685.0251

9.02354.02747.09935.05263.03597.07797,02345.04294.0248

6.01437.0993

5.03873.05206.0089

5.01776.00824.04877.08877.03167.04297.03083.0786

3.08134.0359

9.01126.00897.04597.05067.0857

3.0304

Shock initiation, NM, liquid TNT, DINA,

Shock initiation, nonideal, propellantShock initiation, PBX 9404, HMXfTATBShock initiation, plot, short duration

Shock initiation, reactive modelingShock initiation, role of free radicals

Shock initiation, solid explosives

Shock initiation, TATB and HMX compoundsShock initiation, threshold data, TATBShock initiation, thresholds, hi-density HEShock initiation, two-phase model

Shock initiation, 2D modelShock insensitivity of NQ, electron densityShock interaction, density discontinuitiesShock interaction, theory vs results

Shock intersections, collision effects

Shock loading, response of composite propellantsShock locus, sonic locus calculationsShock pass-heat tllter test, NOL card gapShock polar solutionsShock polars, two Mach stems, x >0

Shock polars for perfect gas, ‘{= 1.4

Shock pressure, aquarium testsShock pressure, high for chemical reactionShock pressure, incidence vs reflection angleShock pressure, water, end & lateralShock profiles (radial vs axial distances)Shock propagation, condensed materialShock propagation, low intensity shock

Shock reaction time test setup

Shock relations to get pressure, shock frontShock retardation in elastic media, cracks

Shock sensitivity, 50% thresholds, preheating

Shock sensitivity, card gap testShock sensitivity, damaged energetic materials

Shock sensitivity, EAKShock sensitivity, emulsion HEsShock &’nsitivity, exploding foil

Shock sensitivity, gap testsShock sensitivity, gap testsShock sensitivity, modified gap testShock sensitivity, numerical modelingShock sensitivity of HMXShock sensitivity of substituted benzofuroxansShock sensitivity, PETN, NMShock sensitivity, pressed booster explosives

Shock sensitivity, RDX crystal shape effectShock sensitivity, reaction thresholdsShock sensitivity, substituted benzofuroxans

Shock sensitivity, TATB/HMX mixturesShock sensitivity test

3.0469

7.06207.0325

4.03769.12179.09873.04998.08928.00055.02197.04357.0488

8.08394.03946.0496

5.01199.0879

6.03527.02669.08426.0574

5.01297.1016

3.08406.04974.00955.04837.07808.0S935,0095

2.0433

6.0268

5.02237.02789.1295

9.00899.0585

7.09248,02289.12849.12357.04799.00259.05669.02359.0098

9.00s38.11359.05617.05737.0479

.



Shock sensitivity testing, EDC35

Shock sensitivity, thresholdsShock sensitivity, TNT, multiple shocksShock sensitivity, vs particle sizesShock strength, critical for initiation

Shock temperature vs particle velocity, TNT

Shock temperature vs velocity, diameterShock-to-cieflagration to detonation (SDDT)

Shock-to-detonation transition (SDT)Shock tube protlle & setup, lead azide

Shock velocity, inert monitors on HEShock velocity, Lucite & water, smear data

Shock velocity, PMMA vs distanceShock velocity, schlieren photosShock velocity, vs particle velocity, PMMAShock velocity, vs distance, TNT, Comp B, ...Shock velocity, vs pressure, overdriven HE

Shock wave, & initiation data for solid HEShock wave, compression of Plexiglas, 3-20 kbarShock wave, converging cylindrical

Shock wave, decay in solids & Al spallingsShock wave, decomposition of HE

Shock wave, effect on porous solidShock wave energy (S WE) for HEsShock wave, evolution, chemical kineticsShock wave, explosive decompositionShock wave, following compression wave, photoShock wave, growth modes, HE initiationShock wave, initiation model, heterogeneous HEShock wave, interaction with condensed HE

Shock wave, interactions, framing-camera recordShock-wave luminosity/product luminosityShock wave, parameters for Mach waves in waterShock wave, parameters for 4 PBX-9404 modelsShock wave, Perspex, pressure effectsShock wave, pressure, attenuator/HE interface

Shock wave, propagation velocity, measuredShock wave, research on inert solidsShock wave, solids, Al=Comp B, TNTShock wave, structure in solids, experimentalShock wave, temperature, Raman scatteringShock wave test, calibratedShock wave, underwater, twin spheresShock width & impulse vs Q & gamma

Shock-capture methodShock-decomposition processesShock-induced deflagration in shells

9.01235.02077.09068.00034.0179

2.0371

6.0332

8.11317.02653.00245.0023

3.05934.02194.05554.02315.0025

5.05334.0233

4.0222

1.00793.0253

9.00504.02589.06336.03796.00294.05726.00476.03717.0778

6.05812.05765.05886.05684.01563.0500

3.04204.03211.00884.05667.1011

8.03615.05816.05639.02939.07249.1322

Shock-induced reactions, thermochemical model 9.1199Shock-light coupling, initiation 9.0172Shock-loading area, initiation threshold 9.0066Shock-[o-detonation transition, 1D model 3.0792

8?

Shock-todetonation transition, light emission 4.0607Shock-to-detonation transition, results 8.0307Shocked multicomponent HEs, model, reaction rate 9.0593Shooting vs barrier test results, velocitiesShort-, long-, sustained-pulse initiation, TATB

Short- & long-pulse initiation threshold, HNS

Short-duration shock initiation of solid HE

Short-pulse shock initiation, granular HE

Short-pulse shock sensitivity testsShort-pulse shock initiation, solid HE, modelShort-shock initiation of TATBShort-shock initiation model

Shortduration-shock response of PBX 9404Short-shock experiments, ID, PBX 9502Shotgun, instrumented facility, propellantsShotgun test, 2DE & FOREST FIRE models

Shotgun tests, rocket propellantSilica impactor, short-pulse shock study

Silicon, polymorphic transformation, detonationSilver azide detonation by light

Silver azide, hot-wire initiationSimilarity solution, reactive Taylor waveSimulants, booster-rocket propellants, characterize.Simulated gun launchSimulation of compaction wave, granular materialSingle-crystal detonation, preparation, testsSingle-crystal experiments, early workSingle crystals, AP, shock loadingSingle cgwtals of HE, theory of shock initiationSingle cubical air-hole study

Single-pore deformation, modelSingle-shocked supracompression testsSingle-species equivalent, JCZ3 EOSSIP gauge for flying-plate detonatorsSize factors in detonation transferSkid test (AWRE) vs LAB SET responseSkid test results, TATB/HMX mixturesSkid test vs L-SET data, explosiveness, HMXSlabs & rods, steady-state wave shapesSlapper detonator, HNSSlapper device, air/gas effectsSLIC method, advected volume, transport modelSlippage routine in Lagrangian flow, modelSlurxy blasting agents, characterization

Slurry explosive, axial initiation studySlurry explosive, Cook-type, boosterSlurry explosive, CS EOS

Slurry explosive, diameter effectSlurry explosive, elemental composition

Slurry explosive, impacted, hot spots modelSlurry explosive, performance, reaction model

4.04326.0757

6.07454.03737.08577.0924

8.09517,0385

8.00529.06049.06577.02997.0479

9.10527.08609.0766

2.0547

5.03398.10269.10609.14809.03062.04693.07919.12609.0235

8.00457.0436

8.05907.07219.082?4.04427.00197.0570

8.10399.07s49.02097.09307.0696

3.02346.07294.01594.04358.08058.0168808107.0343

80985

.

.

.

.

.

.

B. Topic Phrase Index (Continued).

, Subject Sy.Pg Subject sy.Pg

Small-caliber caseless ammunition sensit. 6.0682

Small divergent detonation theory 8.0176

Small-scale dent test, setup 2.0760

Small-scale gap test (SSGT), initiation mechanism 3.0794Small-scale gap test, assembly 4,0401

Small-scale gap test, correlating 7.0888

Small-scale gap test, interstitial gas 4.0349

Small-scale gap test, results, HMX/Viton 4.0090Small-scale gap test, setup, axial air gaps 2.0623Small-scale gap test, SSGT 9.0098Small-scale intermediate gap test 9.0566Small-scale plate dent test, energy release 3.0744Small-scale tests, estimate failure diam, propellant 9.0701Small-scale thermal test, IHE sensitivity

Smear camera record, nitromethane initiationSmear camera record, cyclotol wedge, u,

Smear camera record, 1D & 2D tests

Smokeless powder (E.C. blank fire), DDT studySNI-1 ,-2,-3,-4,-5, liquid HE characterization

Sodatol, wave shape studies, r/DSodium nitrate (SW, EOS of TNT/NAN03 50/50

. Sodium sulfate additive in RDX/TNTSolid HE & other solids, properties, modelSolid HE decomposition, hot-spot reaction

. Solid HE, plane shock wa~re initiationSolid/liquid ratios (S/L) of HE, modelSolid-state model for detonationsSolid-explosive foam (PETN)Sonic angles calculated for Comp B & NM

Sonic or quasi-sonic discontinuity

Sonic point in steady axial waveSonic point properties in plane detonation wave

Soot analysis from TNT/NQ, PBX, RDX/NQ/AlSoot, chemistry of detonationSoot recovery from detonationSophy gap test data for AAB 3267Sound speed c defined, thermodynamic identitySound velocity, (Euler’s) detonation gasesSound veloclty, porous bed unloadingSpace-time history, propagation detonationSpace vs time, shock initiation in solid HESpan calculations for Al, scaling lawsSpan, mesh calculation & wave diagramSpan strengths, rocket propellantsSpalling (scabbing), stress wave resultSpalling detection, Comp B tests & modelSpalling in nickel plate, PHERMEX radiograph

Spalling mechanism, calculation, for copperSpalling under oblique impactSpark initiation in aluminized HESpecies at tlnal state

.

.

7.0965

3.04853.05024.0269

1.00606.04692.0503

2.05195.04654.05556.00293.04997.03432.04049.13644.0154

7.0635

7.0664

9.07579.09629.11709.04177.08923.0543

1.00748.06535.01084.02333.02534.0548

9.10601.00336.04774.06465.0567

5.05733.07069.0906

Specific heat ratio effects on liquid HE

Spectral distribution of light, initiation

Spectral emission, impacted PETN

Spectral response and emission for flyerSpectral slope vs fractal dimensionSpectrograms of shocks in argon & air

Spectrometry, time-resolved, initiation studySpectroscopy, absorption, shocked benzeneSpectroscopy, real-time, detonating HESpectroscopy, time-resolved in vacuumSpectroscopy, vibrational, shocked liq. Nz & NMSpectroscopy, vibrational, shocked Iiq. Nz & NMSpectrum, optical absorption, lead azide

Spherical detonation, converging, solid HE

Spherical detonation, divergent wavesSpherical detonation, surface, liner velocity

Spherical detonation, wave interactions

Spherical explosion, Comp BSpherical explosion shock waves in waterSpherical generator, divergent, calibration

Spherical initiators & charges, underwaterSpherical pore compaction cell model, P vs vSpherical projectile impact on HEsSpherical shock waves in water, twin spheresSpherical shock waves in condensed HE, model

Spherical vs cylindrical vs plane detonationSpherical wave fronts, wave shape studySpherically diverging detonation wavesSpherically-diverging detonation, LX- 17

Sphericity analysis, streak camera record

Spin detonation, viscosity effect

Spin frequency as function of tube diameterSpin Hamiltonian, nitroso radicalsSpin, spot spiraling along tube, combustionSpin trapping spectral dataSpiming detonation, propagating HZ-02Spinning detonation, resonation waveSPIS-44 (HMX/AP/Al) propellant, nonidealSplit-charge experiment, lower pressureSquib- & piston-initiated HMX modelSquib-ignited DDT tube, 80°A compactionSquib-driven DDT experiment

SSS, l-D hydrocode for reactive mediaStability of planar, steady wave frontStability properties of new liquid HEsStages in DDT process for porous chargesStagger scheme, shock & constant state pointsStarch-metal composites, detonability

STARTEX (DITEU) boosters, critical diam., massStatic pore collapse modelStatic stability boundary, deflagration waves

7.0374

5.0153

9.10377.09349.0918

1.00869,01729.01908.069 I5.05609.0172

9.01807.0740

7.0602

5.00316.0521

7.0671

9.07436.05709.1371

5.06008.09159.14275.05816.05285.00412.05048.0151

9.0133

5.0032

7.0796

1.0051

8.07451.00448.07372.02691.00487.0620

4.024 I8.09148.09179.02809.01424.0073

6.04719.03543.02149.0972

4,0435S.09646.0283

83



Stationary deflagmtion in DDT

Statistical mechanical theory, CHEQ modelStatistical mechanics, postdetonationSteady axial plane, reaction zone effectSteady axial wave, detonation state lociSteady condensation air shocks, water vaporSteady detonation in 2D flow, slab & cylinderSteady plane reaction zone, 2ND modelSteady-state detonation wave, finite rateSteady-state detonation, time-dependent model

Steady-state plane detonation wave (SSPD)Steady-state plane detonation wave structure

Steady vs overdriven waves, acetylene-Oz mix

Steady-state waveshapes in rods & slabsSteady-wave (rate stick) experiments, PBX 9502Steel, 4340, effect on wave propagation

Step shock solution in planar flowStilbenes, impact sensitivity and OB ,WStochastic simulationStong point explosion in a combustible mediumStrain rate sensitivity, HMXStrain rate vs strain curves for Comp BStr~in-time plots, tetryl, DDT studyStrain wave, confined, subsonic & plastic

Strand burner, hybrid closed bomb

Strand burner, pressure vesselStreak camera record, sphericity analysisStreak camera record, DDT studyStreak camera record, Comp B, polarizationStreak camera record, convective bum of PETNStreak camera record, dark waves in NMStreak camera record, cylinder testStreak camera record, flyer impactStreak camera record, digital filteringStreak camera record, wave diagram

Streak camera record, shock curvature

Streak camera record, Mach reflection

Streak camera results vs curve fitsStreak images of Al wire combustion in waterStreak schlieren interferogram, reflectedStream tube expansion, Jacobs vs EyringStress histories in shocked PBX 9404Stress-strain data, dynamic recordStress-time profiles of shock & release wavesStress wave interactions, x-t, Fe/free surfaceStress-wave propagation, schematicStress waves, longitudinal, lead azideStresses generated by electric detonators

Stretched HE, effect on detonation velocity

Stroboscopic laser-schlieren records, shocks

Structure, chemistry, & instability in gases

9.02598.0502

7.06467.06617.06662.0296

1.00527.05322.03124.0520

2.04253.0791

2.02039.07849.06574.0295

4.05033.06819.11936.05908.0645

3.04326.04287.0253

9.13103.00805.00325.02355.04326.02536.04176.05126.06567.02967.0680

8.01908.0433

5.0060

9.06414.0071

1.00545.04383.04204.02906.06727.10525.03023.02854.0500

5.01254.0067

Structures & energies, calculated, isomers of NTO 9.1185

Subignition decomposition, chemical products 9.0897Subdetonation reaction, 27 HEs, data base 9.1235Sugar-metal composites, detonability 9.0972Sulfur conductivity pressure dependence 3.0241Sulfur pressure transducer, calibration 3,0241Super gap test setup 8+0~30

SuperVelocity reaction wave model 3,0307Supercritical phase separations 9.0425Superdetonation, SDT 9.0039Supracompressed HE, reaction-zone structure 9.0670

Supracompression, TATB, EOS of products 8.0587

Surface area increase, ignitability & bum 2.0629Surface burning equation, Eyring’s, calculated time 2.0526

Surface burst, ~ndenvater, half-space modelSurface cavities in sample, setback simulator

Surface-coating disruption, RDX grainSurface film effects on external plasmasSurface heat dissipated vs impact sensitivitySurface heat release, deflagration wavesSurface rate processes & sensitivity of HESurface-to-volume ratio of propellantSurface-burning modelSUSAN test, energy release vs impact velocity

SUSAN test, low-velocity impact sensitivity

SUSAN test, sensitivity of IHESUSAN test, TATB/HMX mixturesSustained ID shock initiation, PBX 9407Sustained ignition, mechanical shock, 4-86 kbarSustained-shock experiments, PBX 9502Sustained-shock response of PBX 9404SWE, shock wave energy for HEsSYEP, liquid HE, characterizationSympathetic detonation, shielding roleSympathetic detonation, 2DE model

Sympathetic detonation, AP by NQSympathetic detonation, modelSympathetic de~onation, propellants

Sympathetic detonation, shock inducedSynchro-streak technique, shaped chargeSynthesis of diamonds, detonating condensed HESynthesis of polynitro SF~ model compoundT 1, experimental isentrope dataT2 (TATB), EOS calculationT2, experimental isentrope dataTait EOS, pressure profiles, liquid blastsTait equation, shock transmission through AlTandem single impact, propellants D and E

Tantalum-covered projectile, impactedTarget gauge assemblies, quartz gauge study

TATB, 1D Lagrangian experiments & simulation

5.04939.1480

9.00983.01884.04616.0284

4.04617.0143

9.06046.07554.04777.09657.05709.1224

9.12359.06579.06049.06336.04699,14897.1055

6.01737.0479

6,0302

3.05207,0751

9.04079.11628.08158,07518.08206.05021,00918.0286

7.03255.0376

9.0252

,

.

.84

.

B. Topic

Subiect

Phrase Index (Continued)

Sy.Pg Subject sy.Pg

TATB, 3D hydrodynamic hot-spot modelTATB/AP, cylinder test data, temperatureTATB-based customized explosivesTATB, chemical decomposition modelTATB, CJ point, CJ isentrope, emor ‘Y.

TATB, CJ properties, oxygen balance

TATB, comer-turning dataTATB, crash-precipitated pore-size tests

TATB, crystallographic cell parametersTATB, detonation parameters, interpolation

TATB, detonation products EOS

TATB, detonation properties, carbon EOSTATB, detonation reaction zone studiesTATB, Doppler laser interferometer studyTATB, EB initiation, two exothermic reactionsTATB, expansion isentropesTATB, flyer plate initiationTATB, front curvature, reaction zone lengthTATB HEs, electron-beam initiation

TATB/I-IMX compositions, customized PBX

TATB, hot spots’ nature

. TATB, hydrogen bonding

TATB, initiation & detonation characteristicsTATB, initiation studies of LX-17 & PBX 9502

. TATB, isothermal linear & volume compressionTATB, jet penetration modelTATB/Kel-F, electron beam initiationTATB/Kel-F, receptors in gap testsTATB/Kel-F, double-discontinuity model, gapTATB/Kel-F, confinement effect on failureTATB/Kel-F, sustained pulse initiation, wedgeTATB/Kel-F 800 95/5, initiation & detonation

TATB, low density, shock initiation

TATB, LX-17 shock initiation vs temperatureTATB, particle size distribution effects

TATB performanceTATB,

TATB,TATB,TATB,TATB,TATB,TATB,TATB,TATB,TATB,TATB ,

TATB,TATB,

planar shock initiation, gauges, wedgesporous, shock initiationpropagation of detonation from impactRaman spectra of shock-compressedreaction zone, steady axial wavescanning electron photomicrographsSDT, run to detonationsensitivity, short & long pulsessensitivity with ammonium nitrateshock initiation, tests and modelsshort-pulse sensitivity

standard gap test, bum modelsynthesis

TATB/T2 Hugoniot

TATB, thermal decomposition of contlned HE

8.00448.10207.05667.00567.0709

8.05477.0624

8.0003

6.07057.1029

9.0506

8.05288.01238.01357.00508.08156.67566.06429.11317.0567

9.0897

9.0153

6.07558.10456.07008.03377.00527.02797.0294

8.03726.0764

9.01237.0385

9.0112

8.00039.0478

7.03857.0385

9.07989.01537.06617.0427

8.03807.04257.0804

8.08927.0390

7.04827.0425

9.0379

6.0214

TATB, thermochemical dataTATB/Viton, transport modelTATB, vs DfNGU, comparison of propertiesTATB, vs HMX, confined drop hammer testTaylor analysis of a tubular bomb

Taylor instability, same as Landau’s (Russian)

Taylor model simplified and extended

Taylor wave calculated for pentolite

Taylor wave, energy transfer to rigid pistonTaylor wave fits, RICSHAW, manganin gauge

Taylor wave in P-t curve

Taylor wave, inert binders effectTaylor wave p-T, pyrometer, in situ gaugeTaylor wave region, nonsteady 1D flowTDPF, liquid HE, characterizationTeflon 7C, compaction in porous beds

Teflon 7C, sound velocities vs % tmdTeflon 7C tests, strain rates of HMXTEGDN, gap test sensitivity in propellants

Temperature dependence of density for NM

Temperature, detonation, measurement, HN/HH

Temperature effect, cobalt amine azides

Temperature effect, composite HETemperature effect, detonation velocity of NMTemperature effect, diameter effect, NMTemperature effect, diverging detonation waveTemperature effect, gap testTemperature effect on LX-17 shock initiationTemperature effect, precompression studyTemperature effect, propellantsTemperature effect, secondary explosives

Temperature effect, shock initiationTemperature effect, shock ignition

Temperature effects, propellant detonation

Temperature evaluation, SDT explosion phaseTemperature in reaction zone, light intensityTemperature, optical system for measurement

Tempe~6ture profiling, FTIRTemperature, shock wave environmentsTemperature, shocked HE, IR radiometryTemperature-time curves, ideal gas vs BKWTemperature variation, initiation of liquid HETemperatures, calculated on an isentropeTemperatures, calculated, TATB, vs pressureTension contours vs observed fracture patternTensor model, hot spots in slurry HETetrazole, time to explosion

Tetrazoles, electronic structureTetryl, booster replacementsTetryl, bum rate, sensitiveness, Q, m x Q

Tetryl, calculated & test detonation velocities

9.04897.0697

7.05407.09668.0604

1.01058.0602

4.00333.0206

6.0625

3.0249

7.05648.05647.05316.04697.08437.02048.0648

3.0830

2.04559.0939

3.0053

8.10182.04552.04618.10477.03369.01125.00773.0828

5.02795.0219

7.0459

9.0537

9.02194.06021.0017

9.022S7.10047.09937.03485.01539,11999.01535,05797.03449.02287.0071

8.11052.0651

2.0418

.

85



Tetryl, contact film, drop-weight impact testTeu-yl, DDT studies, plastic tubesTetryl, density, detonation velocity, pressure

Tetryl, detonating centering deviceTet~l, detonation flame analysis

Tet~l, detonation front temperature

Tetryl, detonation pressure profileTet~l, detonation properties, carbon EOSTetryl, detonation temperature vs densitiesTetryl, detonation temperature measurementTetryl, diameter effect, D vs l/dTe[ryl, direct-contact detonation sensitivity

Tetryl, EM.P velocity gaugesTetryl, EMV gauge, pressures & times

Tetryl, experimental vs computed HugoniotsTetryl, exploding-foil shock effectTetryl, gap test for liquid HE, NG/EGDNTetryl, gap test calibration resultsTet~l, gas pockets, low-velocity detonationTetry 1, heat of detonation, unconfinedlconfinedTetryl, high-vacuum detonationTetryl, impact initiation, .30-cal. cylindersTetryl, impact sensitivity, critical tempTetryl, impact sensitivity and OBIWTetryl, laser ignition testTewyl, linear memory effect

Tetryl, linear surface regression, 500°CTetryl, mechanical properties, drop weight

Tct~l, particle size effects, small-scale gap

Tetryl, pellet initiators in NOL gap testTetryl, products in preignition reaction zoneTetryl, radicals in decomposition products

Tetryl, retarded detonation, tricks (chicanery)Tetryl, single-crystal tests, propertiesTetryl, small-scale gap testTet~l, temperature, measured and calculatedTetryl/wax, x-t plot, strain-t plot, DDT effectTFA, liquid HE, characterizationTFMA, liquid HE, characterizationTFMDA, liquid HE, characterizationTFMFF, liquid HE, characterizationTFNA & TFENA, BKW model & perfoxm. dataThermal decomposition of [CO(NH, )6 I(N,)3Thermal decomposition rate constants

Thermal decomposition reaction, confined HEThermal decomposition velocities, sensitivity

Thermal exploslon chemistry, gas products, timeThermal explosion theories, gaseous systems

Thermal explosion theory, reaction rateThermal explosion time at m.p. vs pressure

Thermal explosion times, critical diameter

S6

3.00137.0119

3.03788.03322.0572

9.09399.04718.05288.0573

9.09474.01824.0405

8.0447

5.0413

6.07737.0928

3.04387.0288

2.05843.07505.05612.06123.00693.06748.04763.00474,0461

8.0642

S.0259

3.05859.0162

8.07426.02262.04709.0098

8.05586.04346.04696.04696.0469

6.04693.07313.00505.0166

6.02143.00609.0228

2.05636.00767.00375.0102

Thermal explosions, EB heating, heat flow oven 7.0062Thermal hazard of dynamite, modeling 7.0043Thermal ignition & combustion, heterogeneous HE 9.1070

Thexmal initiation & reaction, secondary HE 5.0279Thermal initiation, electron beam, model 7,0050Thermal initiation, memory effect 3.0042Thermal initiation, role of free radicals 9.0987Thermal response of intermediate explosives 8.1105Thermal test, sensitiveness testing 3.0660Thermal test, sensitivity test, small scale 7.0965Thermal wave, energy motion 5.0361Therrnite Hugoniot, calculated 9.1199Therrnohydrodynamics in metalized explosives 2.0733Thermochemical model, shock-induced reactions 9.1199Thermocouple configuration, thermoelectric study 4.0628Thermocouple design for shock wave locus 7.1005Thermocouples, measuring time to exotherrn 9.0228Thermodynamic equilibrium in detonation waves 2.0198Thermodynamic functions, detonation products 8.0799Thermodynamic functions, gas & solid phases 2.0384Thermodynamic parameters distribution 7.0789Thermodynamic path in (P,V) plane 7.0693Thermodynamic properties, inverse method, EOS 2.0S22Thermodynamic state from detonation velocity 1.0072Thermodynamics, influence on hydrodynamics 8.0788Thermodynamics of detonation products 7.0759

Thermoelectric effect, shock press transducer 4.0627

Thermograms of emulsion HEs 9.0585

Thermokinetic parameters, tetryl, RDX, HNS, ... 8.1112

Thennomechanical coeftlcient vs amplitude 6.0386Thin foils confining detonation wave 6.0406Thin-layer chromatography (TLC), subignition 8.0725Thin-metal films, confined, shocks generated 6.0614Thin-pulse initiation, LX- 17, velocities 8,1051Three-dimensional (3 DE) hot-spot model 8.0042Three-rate-equation model, initiation of PBX 9502 9.0657Threshold impact velocity of jet vs diameter 9.1416

Threshold for j~t initiation, predicting 9.1404Threshold for laser initiation, PETN, HMX, HNS 9.1100Threshold gap values, cavitation effects 7>0376

Threshold initiation, LX-1 3, PETN, PBX 9407, ... 8.1091Threshold pressure vs reciprocal charge diameter 4.0446Threshold velocity data, Comp B, TNT, tetryl 8.1151Thurston’s stress gradient model, span study 6.0487

TIGERfBKWR EOS for eutectics of EDD and AN 7,0555TIGER parameters, BKW, BKWR, JCZ3 6.0720

TIGER calculations, baratol 9.1378TIGER calculations, pinned-wedge tests 9.0025TIGER code calculation for starch/Al 9.0972

TIGER code calculations of DDT 9,0320

TIGER JCZ3 adiabats, EMULITE vs air, P-uP 8.1077

.

.



TIGER model, CP detonation properties

TIGER model, detonation pressure calculations

TIGER model, matched to CJ from JCZ EOS

TIGER model, nitromethane EOS

Tilt control of impact surfacesTime dependence vs method of characteristicsTime to onset of compressive reaction, DDTTime-dependent 1D unsupported detonationTime-dependent absorp. spectroscopy, CbH~

Time-dependent behavior, composite explosivesTime-dependent detonation waves, curvaturesTime-dependent flow behind detonation front

Time-resolved conductivity, detonating HE

Time-resolved infrared radiometry

Time-resolved infrared spectral photog., TRISP

Time-resolved mass spectraTime-resolved mass spectrometryTime-resolved radiation in reaction zoneTime-resolved spectrometries in initiationTime-to-exotherm, thermocouple measurementTMETN, shock compression through inert, DDT

. TNB, direct-contact detonation sensitivity.

TNB, time delay vs temp reciprocal, decomp.TNETB, impact sensitivity, critical temperature

. TNM/Al isentropic behaviorTNM/C, cylinder test data, temperature effectTNM, detonation velocitiesTNM, LVD & HVD in liquid HE, card gap testTNT, 2D Lagrangian probe

TNT, 500-ton hemisphere, photograph

TNT, air gap effect on propagationTNT/AN + Al, detonation products analyzed

TNT/AN, diameter effect, D vs I/d, limit dataTNT/AN, v-d curves, wave shape vs d, kineticsTNT, anomalous bum rate characteristicsTNT, base gap effect on sensitivity, NSWC testTNT, BKW model & performance dataTNT, bubble energy, underwater expansionTNT, burn rate, sensitiveness, Q, m x QTNT, calculated & test detonation velocities

TNT, calculated detonation temperatureTNT, calculated pressure pulse shapesTNT, cast, low-temperature propertiesTNT, cast, multiple Lagrange gauge studyTNT, cast, numerical modelingTNT, cast, shock compressibility differencesTNT, chemical decomposition modelTNT, chemical reaction, fracture result

TNT, chemistry in free expansion of HE productsTNT, CJ data & calculated CJ parameters

TNT, CJ point, CJ isentrope, error ?4.

7.0870

5.00287.0725

7.0610

5.03824.05209.03066.03529.01906.0729

1.00996.0637

9.03967.0993

9.0153

9.01629.11404.06029.01729.02283.08134.0407

3.00683.00697.09428.10228.05384.0412

9.00778.0410

8.04098.05774.01822.0733,7.08987.09143.07286.05462.0651

2.0418

1.00747.09106.00366.07869.02507.07937.00568.02439.09536.07137.0709

TNT, CJ properties, oxygen balance

TNT, CJ state for cast, modelTNT, Comp B, bum rate anomalies

TNT, conductivity profiles, C precipitationTNT, confined, after tiring, deflagration

TNT, critical length vs critical velocityTNT, crystal structure, sensitivenessTNT, crystal structure in cast blockTNT, curvature effect on shock waveTNT, cylinder test results

TNT, cylinder with air bubble, deformationTNT, diameter-effect parameters

TNT, decomposition in shock wave

TNT, deflagration rate, modeling

TNT, density, D, cd, experimental pressure

TNT, density, shock & particle velocitiesTNT, detonability in propellants & explosivesTNT, detonation behavior of liquidTNT, detonation decay velocityTNT, detonation parameters, Chinese testTNT, detonation pressure profileTNT, detonation propagation data, gap testTNT, detonation temperature measurement

TNT, detonation velocity vs densityTNT, detonation-front temperatureTNT, dop-weight impact testTNT, dural, u=TNT, direct-contact detonation sensitivityTNT, detonation properties, carbon EOS

TNT, detonation temperature, pyrometerTNT, EMV gauge, detonation pressures & times

TNT, EMV particle velocity mess. in detonatorTNT, energy vs reaction responseTNT, energy vs reaction responseTNT, EOS and thermal decomposition rateTNT, exploding-foil sensitivity effectTNT, explosively driven metal, modelTNT, f~acture surface topographyTNT, gas pockets in low-velocity detonationTNT Hugoniot

TNT,TNT,TNT,TNT>TNT,TNT,TNT,TNT,TNT,

TNT,

Hugoniot curves and sound velocitiesHugoniot data for unreacted explosiveHugoniots, derivatives along shock pathignition by air gap compressionignition thresholdimpact sensitivity and OB ,Wimpact sensitivity and oxygen balanceinert-explosive interface studyinitiation and propagation, model

JCZ state, molecular parametersTNT labeled with ‘3C

8.0547

7.0364

7.0898

4.05996.0204

4.04323.06668.04121.00994.00056.0340

6.0647

9.0050

7,0175

3.0376

4.02453.06372.0439

1.00158.04409.04716.00409.09479.0443

9.09393.00062.03334.04068.0528

8.05745.04139.0816

6.00036.00073.035?7.09298.06109.09182.0584

9.03794.0235

5.02516.07917.00039.14603.06813.07016.0029703627.072190407

37



TNT, large-scale gap test, critical diameterTNT, laser ignition test

TNT, linear surface regression to 500”CTNT, liquid, modified gap testTNT, liquid/solid, energy threshold, P-t plot

TNT-loaded EB W initiationTNT, low-pressure point on isentropeTNT, low-pressure, low-velocity shocks

TNT, low-temperature initiation

TNT, luminosity records, detonation temps

TNT, measured detonation pressure, aquariumTNT, mechanical properties, drop weight

TNT, molecular geometry, bond lengths, ab initioTNT, multiply shocked, sensitivity effectTNT/NQ + Al, detonation products, QTNT/NQ, detonation products in argon & vacuumTNT/NQ/wttx, gap test resultsTNT, oblique shocks, perpendicular driveTNT, overall energy balance

TNT, overdriven shock HugoniotTNT, overdriven shocked statesTNT, particle velocities, Lagrange gauges

TNT, performance, Q, Cu cylinder testTNT, physical properties, grain growthTNT, Plexiglas monitor, shock velocityTNT, porous, response, model & dataTNT, pressed & cast, shock wave propertiesTNT, pressed, detonation velocity vs diameterTNT, pressed, jet initiationTNT, pressed, light-gas gun impact

TNT, pressed, physical characteristicsTNT, pressed, wedge test & smear camera dataTNT, pressed with liquid in poresTNT, pressure pulses, free-surface velocities

TNT, pressure shear ignitionTNT, properties compared with those of DATBTNT, radicals in decomposition productsTNT/RDX, 90/1 O to 30/70

TNT/RDX/wax, runup distance and gap testTNT reaction productsTNT, reitction zone length calculatedTNT, reacuon zone structureTNT, receptors in gap testsTNT, retarded detonation, tricks (chicanery)TNT/salt mixtures, quenching effect of saltTNT, sensitiveness of liquid & pressed grainsTNT, sensitivityTNT, sensitivity and explosiveness

TNT, sensitivity and performance data, SDDT

TNT. sensitivity with ammonium nitrate

TNT. shock compression through inert, DDT

5.02078.04764.04617.03106.01064.0452

3.03894.0239

6.00362.0158

5.0065

8.06428.08307.0906

8.05779.09628.02286.06026.0559

9.04435.05337.1074

9.0478

1.00325.00236.07669.00503.03278.03186.00036.00063.05049.07247.0910

9.0003

3.0769

8.07429.04077.0336

9.09625.00239.06707.02796.02262.05092.06437.0373

8.02658.1132

7.0804

3.0813

TNT, shock front velocity in vacuumTNT, shock-induced phrtse change

TNT, shock temperature in modelTNT, shock wave transmission through AlTNT, shocked, heat-sensitive film recordTNT, single-crystal tests, propertiesTNT, slurry, calculated blasting performanceTNT, snow-flaked packed, CJ pressures

TNT soot, mass spectrum, ODTX

TNT, temperature, measured and calculated

TNT, thermal decomp. at P = 10-50 kbarTNT, thermal decomposition of confined HETNT, thermal initiation and growthTNT, thin-tlyer plate impactTNT, time delay vs I/T, decompositionTNT, TNT/NM, electrical transducer studiesTNT, unconfined cylinder, test, 2DL modelTNT, undenvater shock-to-bum testsTNT, wave curvature vs charge length, I/d <3

TNT, wax gap test

TNT/wax, gap test resultsTNT, 2ND proof, inductiordchemical reactionTNTB, bum rate, sensitiveness, Q, m x Q

TOODY model, NM failureTopography, fracture surface of HEsTorching experiments, simulationsTorpex 2B, sensitivity and explosivenessTorpex, low-order reactions--reaction zoneTorvik’s method, Hugoniot for mixturesTP-H 1207C propelhtnt, characterization

4.0176

5.02577.0463

1.00907.0973

2.04708.09872.0380

9.11708.0558

5.03316.02145.02809.00663.00674.06095.03134.0489

2.0504

1.00238.0228

2.03582,065 I7.0609

9.09188.02158.02654.046?9.00349.1060

TR4NBA subro~tine to RUBY program, isentropes 4.0168Transducer studies, initiation of liquid HE 4.0609Transient combustion process, model 8.0940Transit times = sound speeds & initial slopes 4.0240

Transit times in HE charges, pin method 2.0136Transition pressures and slow bum 3.0085Transmission & growth of detonation 2,0620Transparent anvi): drop-weight apparatus 8.0635Transparent liquid-HE optical emission 8.0015Transport-controlled reaction, model 7.0521Transport model, SLIC method, advected volume 7.0696Transport phenomena, detonation wave effect 3.0537Transverse displacement test setup 2.0637Transverse wave effects, condensed HE, photos 6.0414Trapezoidal prism shot assembly, PBX 9502 8.0373Trauzl test, methyl nitrate sensitivity 5.0268Trinitroanilines, EPR spectrum 8.0746Trinitroaromatics, UV & thermal decomposition 8.0742Trinitromethyl compounds 7.0090Trinitromethyl compounds, impact tests, OB ,M 3.0675Triple sphere, wave forms, velocities 8.0089

.

.

●

✎

.

.



Triple-wave initiation model, insensitive HE 7.0373TRISP feasibility, CHNO decomposition kinetics 9.1140TRISP, time-resolved infrared spectral photography 9.0153

.

1rltonal a H15x, Veloclty-diameter curvesTritorml, gap test results

Tritonal, Hugoniot data for unreacted HE

TS 3659, DDT studiesTS3659, compressive reactionTS3659 propellant, numerical simulation of DDTTS3659, therrnophysical & material property dataTS3659, x-t DDT dataTTF, liquid HE, characterizationTube-wall motion, flash x-ray photographTungsten, shock wave vs particle wave velocity

Tungsten strikers, oscilloscope tracesTurbulence effects on gas detonation in tubes

Two-dimensional initiation modelTwo-dimensional shock wave velocity

Two-stage light-gas gun, shocked CcHdTwo-step combustion model, granular materialsTZL-4, time to explosionUFD particle-size distributionsUFD, ultmfine-diamonds from detonating HEUGS propellant, characterizationUltracentrifuge tests, fracture results

Ultrafast laser microphotographyUltrasonic measurement of D & [empUltrasonic wave velocity, elastic moduli, PETN

Ultrasonic welding hazardUltraviolet light initiation of azides

Underwater deflagration, lead azide crystals

Underwater detonation, acoustic half-spaceUnderwater detonation, AN emulsion HEsUnderwater detonation, artificial viscosityUndenvater detonation, bubble expansionUnderwater detonation, density effectsUnderwater detonation, spherical interaction

Undenvater detonation, surface burst modelUnderwater explosion, emulsion HEs

Undenvater explosions, bubble effectsUndenvater explosions, shock wave effectsUnderwater explosions, simple analysisUnderwater explosions, spheres, calibrationUnderwater explosives, optimizing flowUnderwater gap test, calibration, PBX 9205Underwater HE detonation, chemistry

Underwater HE use, shock wave & bubbleUnderwriter HEs, performance estimate

Underwater sensitivity test, hot spots

Undenvater sensitivity test

Underwater shock, initiation to bum

L.V”13 I

8.0228

5.02519.03549.03419.03299.0293

9.03066.0469

7.07997.0831

2.0562

2.02557.0316

8.00899.01909.0293

9.02289.04079.04079.10608.02439.06411.00316.03967.0043

2.0547

5.03055.04939.06215.05976.05406.05615.05815.04939.0641

1.00086.05616.05025.05996.05515.05999.06261.01079.0633

7.0973

9.12354.0487

Underwater shock input, TATB, HMX, & AP

Underwater shock, methods

Underwater shock, molecular subignition tests

Underwater shock, pressure P, vs r/rO

Underwater shock, waves from pentoliteUnderwater tests, ANFO, nonideal detonation

Unreacted Hugoniot, emulsion HEUnsteady & regular Mach reflection, waterUnsteady ID shock waves in solid HEUnsteady condensation 3D shocks, jet formedUnsteady detonation growth, solid HEUnsteady flow equations, Eulerian, Lagmngian

Unsteady flow, plane, Lagrangian equationsUnsteady motion of perfect fluid, ID model

Unsteady shock propagation in reactive media

UP (ureamonoperchlorate), water solubleUranium, conical implosion, vaporization

UV-irradiated HMX, shock transit timeV2d jet initiation criterion

Vacuum detonation, TNT/NQ and TNTIANVacuum, explosives, front velocitiesVacuum gap test setupVan der Waal’s one-fluid mixture modelVariable-density HE, foamsVelocimetry, Fabry-Perot interferometryVelocities, D & plasma, vs oxygen balanceVelocities, detonation & deflagration, probeVelocities, electonic streak camera recordVelocities, multiple release rates, unloading

Velocities, particle velocity-time records for CPVelocities, particle velocity, HE/window interface

Velocities, vs embedded gauge vs reactive flowVelocity-diameter dependence, critical diameterVelocity-diameter predicted relationshipVelocity-pressure data, aquarium testsVelocity record, oscillograph trace, PETN

Velocity vs curvature radius, detonation waveVenting’by orifice flow, de flagration modelVibrating solid, partition function

Vibrational energy transfer in HEVibrational modes, TATB Raman spectraVibrational spectroscopy, molecular initiationVibrational spectroscopy, shocked Iiq. N: & NMVibron level, lattice density, PETN & NMVickers hardness test, RDX deformationViolence of HE response compared to sensitivityVirial EOS of detonation products, TATBVirtual piston in DDT

VISAR, dial-delay leg, digital recorders

9.0897

3,0795

8,07256.05874.00273.03159.05736.05703.05352.03043.05346.0582

3.0213

4.0503

4.05026.0450

5.0547

8.08479.14168.05794.01767.00057.06469.13649.13713.01924.06168.04697,08577.0871

8.0016

8.09556.03447,0589

5.00651.00132.042470175

2.04069.02359.01539.01729.01809.02357.0977

9.14609.0506

9,0?65

6.0669VISAR, mess. of HNS mild detonating fuse output 9 151u

VISAR-measured waveforms 7.0402

39


Subject Sy,Pg Subject sy.Pg .

VISAR on TNT & RDX 9.0050VISAR PSF gauge, data comparison 9.0822VISAR, reaction-zone struct., supracompressed HE 9.0670Viscopktstic model, hot spots in shocked HE 7.0435Viscoplastic work, collapsing cavities 8.0068Viscosity & heat transfer effects in codes 3.0803Viscosity effect, detonation wave theory 7.0795Viscosity effect in growth of detonation 3.0534Viscosity vs temperature, 3 liquid HEs 6.0470Viscous heating, efficient for shock condition 8.0068VLW EOS, CJ calculations for CHNO HEs 8.0796VLW EC.)S, comparison with BKW and LJD 8.0796VLW EOS, predicting detonation parameters 9.0435Void & gas bubble effects, surface reaction 3.0518Void collapse model, shock initiation 7.0506Void collapse, role in initiation 9.0842Void gas effect on temperature measurement 9.0947Void model, dynamic compaction process 8.0929Void volume effect, surface reaction mechanism 4.0402Voldage, effect on reaction rate 9.0197Voids, decreased velocity and pressure 2.0629Volume & pressure dependence, kinetics of HE 6.0305von ,Neumartn detonation theory, 2D extension 2.0424von Neumann model, analysis & proof 2.0312von Neumann-Richtmey er, Q method, hydrocode 3.0226von Neumann-Richtmey er, Q method, models 3.0723von Neumann spike, CJ condition 1.0107von Neumann spike, oxidation reaction zone 2.0212von Neumann spike, in pressure-time curve 3.0249~’on Neumann spike, density, estimating 4.0078von Neumann spike, pressure, PMMA disks on HE 4.0244von Neumann-spike pressure, LX-17 9.0133VOY propellant in DDT studies 7.0146WAK-2 propellant, characterization 9.1060Walker-Wasley criterion, flyer plate impact 8.1093Wall effect on EDC35 detonation velocity 9.0831Wall traces of detonation, NM, test methods 5.0105Wall velocities calculated from fit to data 6.0518Water (also see aquarium)Water-control tests, precursors identified 5.0081.Water, isentropes & isotherms, calculated 4.0030WaLer, shock pressure vs shock velocity 3.0369Wat’e curvature tllm, wave trace 2.0446Wave curvature increase, reaction zone width 6.0405Wave curvature measurement method, liquid TNT 2.0443Wave curvature vs diameter & density, ideal HE 2.0500Wave diagrams, spalling calculations 6.0482Wave front patterns, impacting plates, diagram 5.0576Wa\’e front solution, nonideal 1D model 8.1026Wave propagation, 2D hetero- & homogeneous 6.0405Wave propagation, after shock initiation, x-t 3.0306

90

Wave propagation, elastic-plastic materials

Wave propagation in EDC35Wave propagation, single crystals, PETN

Wave reflections in target, Comp B/AlWave shape effects from inert additivesWave shape measurements in aluminized HEWave shape vs particle size, d, nonideal

Wave shapes, steady-state, rods & slabsWave structure, rotating-mirror cameraWave surface curvature effects, shock wavesWave velocities, ultrasonic, elastic moduliWave velocity-elastic stiffness modulusWave-front curvatureWaveform records, conductance, flat probes

Waveforms, PBX 9404 models and testsWavelength dependence, laser initiation

Wax, desensitizing against cavity initiationWax, effects on sensitivity of HMX/wax

Wax, effects on sensitivity

Wax-gap sensitivity test, NOL, setup & dataWC 231, double-based propellant, DDT studyWC 140, compressive reactionWC 140, thermophysical & material property dataWC231, therrnophysical & material property dataWCA self-consistent EOS models

WCA theory, simplified in BKW-EOSWCA4-calculated CJ pressureWCA4 EOS, CJ calculation, CHNO explosiveWCA4 EOS, intermolecular potentialsWeak condensation detonations, gas flowWeak detonation, polymorphous transformationWeak detonation solution, Taylor, Friedrichs

Wedge experiments with NM, TNTWedge test, particle-size effect on PBX

Wedge test, baratol

Wedge test, brass-PETN, 2.5-kbar initiationWedge test, data, better

Wedge test, emtikion propertiesWedge test, liquid NO, cold, gas gunWedge test, modeling, PBX, 2D JWLWedge test, new, no confinement effectWedge test, no resonation, camera record

Wedge test, parameters & setup, DATB, (NOL)Wedge test, plane wave, schematicWedge test, setup, streak camera recordsWedge test, velocity vs time, HZ-02 mixesWedge tests & rate sticks, HMX/AP/AlWedge tests, HMX formulationsWedge tests, pinned, HMX, particle size

Weierstrassian elliptic function, flow talc.

Welding, jetless & jet forming with sheet HE

4.0295

9.1243

6.03972.03682.0508

2.07392.0512

9.07845.00976.0379

6.03966.0398

9.08064.05988,0932

9.11182.06814.03997.0336

1.00228.06589.0341 I

9.0293 ,I9,0~93

8.0521 .7.07047.0716

8.07517.07032.02959.07662.03046.0013

9.00189.1378

3.05634.0234

9.05739.13359.12178.03723.05043.07705.02218.09052.02707,0620

9.00259.00254.0016

4,0499

.

.



WG2 & 4, MMAN sensitive watergelsWhitham’s method, propagating shock wavesWhitham’s rule, extended, underwater blasts

Whitham’s shock dynamics theory, divergentWien’s radiation equation, detonation temperature

Wilkins EC)S, modified, dip below constant y

Wilkins EOS of detonation products, TATBWilkins form of EOS, dip in CJ adiabatWire bridge in EBW initiator

Wire heating, high-speed microphotography

Witness foam, CJ conditions in foamed PETNWitness plate dent from prism testWitness plates, high-density effects on tests

Wendy, 1D Lagrangian model, shock & rampWendy model, nitromethane failureWONDY, 1D Lagrangian propagation code

Wood-Kirkwood diameter effectsWood-Kirkwood equations, curvature effect, DWood-Kirkwood results, diameter effects studyWood-Kirkwood theory extended, 2D detonationWood-Kirkwood reaction zone lengthWood-Kirkwood theory, noniderd explosives.

. X-0204, cylinder test resultsX-02 19, 2DL wave propagation, model vs data

●X-02 19, front curvature, reaction zone lengthX-02 19, wave surface curvature effectsX-023 3, tungsten-loaded HMX, detonation tests

X-0242, performance & sensitivityX-0290, diameter-effect parametersX-0290, failure radii, data & modelX-0290, 12C photo, initiation on back faceX-0290, particle velocities, magnetic probeX-03 19, composition, densityX-03 20, composition, densityX-03 21, composition, densityX-034 1, composition, density

X-0342, composition, densityX-0343, composition, densityX-0344, composition, densityX-0344, tensile propertiesX-0407, detonation reaction zone study

X-0420 performanceX-0430, perfomnance & sensitivityX-0432 performanceX-043 8, perfomnance & sensitivityX-0444, performance & sensitivityX-ray absorption photometer, detonation tubeX-ray initiation of azidesX-ray photoelectron spectroscopy (XPS)X-ray photoelectron spectroscopy (XPS)

X-ray study of DDT in granular HMX

6.05464.01456.0502

9.0784

2.01574.00549.05064.0024

4.0450

9.06416.01888.03745.0047

7.03947.0609

9.02092.04244.0086

6.06517,0589

9.08069.01974.00056.0411

6.06506.03798.09799.10146.06476.0412

6.06676.06377.05677.0567

7.05677.0567

7.05677.0567

7.0567

8.06378.01239.04789.10149.0478

9.10149.10142.01882.05658.62438.07259.0265

X-ray tomography of HE defects

X-ray topography, LiF strain tleldsX2 (HMX), EOS calculationXDT, ANFO, double-pipe testXDT definition, reactions

XDT, distance to detonation dataXDT, propellants, rarefaction, and compaction

XDT reaction, instrumented shotgun tests

XDT reaction, threshold velocitiesXenon arc image furnace, propellant study

XM39, detonation characteristicsXNOVAK code for DDTXPS, HE reaction product, subignition regime

XPS spectra, HMX, RDXXPS spectra, RDX, TNT, AP, TATB

XPS, x-ray photoelectron spectroscopyXTX-8003, diameter-effect parametersYAG laser, temperature behind shock waveYIZUM, 1D Lagrangian initiation model

Z-TACOT, detonation properties, carbon EOSZeldovich reaction zone, pressure vs distanceZeldovich-von Neumam priority claimZero-pressure limit of Hugoniot vs sound speedZeroth-order internal structure, solid HEZND detonation spike point, NM study

2ND model, chemical reaction zone2ND model, chemical reaction zone

2ND model, Chinese detonation research2ND model, particle velocity histories2ND model, shock amplitude evolution2ND model, steady detonation reaction2ND pressure, nitromethane mixturesZOX, chemical and detonation propertiesZOX properties and formulations

ZrHz-based composites, reactive flow mess., talc.

9.08687.0982

8.07518.03907.0265

8.08888.0284

7.03017.0259

7.0217

9.0537

9.03298.0725

9.08978.07289.08976.06477,10107.05068.05281.00461.01054.03447.0686

7.06107,0369

7.0641

7.07957.0488

6.03827.05317.05869.0985

9.09959.0525

.

.

.

IC. Author Index

Alphabetic

Name Sy.Page

Ablard, J. E.

Abouseif, G. E.

Adams, G. K.

Adenis, J. C.

Adolph, H. G.

Adolph, H. G.

Agnew, S. F.

Agnew, S. F.

Aks[, 1. B.

Akst, I. B.

Akst, I. B,

Akst, I. B.

Akst, I. B.

Alcon, R. R.

Aldis, D. F.

Aldis, D. F,

Alexander, K. E.. Allan, J. W. S.

Alkm, J. W. S.

Allison, F. E..Alster, J.

Amery, B. T.

Amster, A. B.

Amster, A. B.

Andersen, W. H.

Andersen, W. H.

Andersen, W. H.

Andersen, W. H.

Anderson, R. D.

Anderson, G. D.

Anderson, C. J.

Anderson, A. B.

Andersson, B.

Andrew, M. 1.

Andrews, G.

Andriot, P.

Anisichkin, V. F.

Antipenko, A. G.

Arbuclde, A. L.

Arbuckle, A. L,

Arbuclde, A. L.

Arbuckle, A. L.. Argous, J. P.

.

1.00s8

6.0502

4.0502

8.0892

7.0084

7.0952

9.1019

8.0715

5.0059

7.0548

6.0439

8 1001

9.0478

9.0039.

9.0280

9.0112

9.0498

4.0052

4.0014

3.0112

3.0693

6.0673

4.0126

3.0584

7,0459

6.0682

4.0205

5.0067

7.0198

4.0213

9.1364

7.0385

4.0602

9.1253

8.0099

9.0506

9.0407

6.0143

7,1055

8.0943

9.1489

8.0307

4.0135

Name Sy.Page

Armstrong, R. W

Armstrong, R. W,

Arnold, W.

Asaba, T.

Asay, B. W

Asay, B. W

Aseltine, C. L.

Atwood, A. I.

Atwood, A. I.

Aubert, S. A.

Austing, J. L.

Austing, J. L.

Austing, J. L.

Austing, J, L.

Aveille, J.

Aveilh$, J.

Aveille, J.

Aveille, J.

AveillA, J.

Aveille, J.

Aviles, J. B.

Avrami, L.

Avrami, L.

AyaIon, D.

Aziz, A. K.

Baconin, J.

Baconin, J.

Baer, M. R.

Baer, M. R.

Bahl, K. L.

Bahl, K. L.

Bahl, K. L.

Bai Chunhua

Bailey, W. A.

Bailey, W. A.

Bainville, D.

Baker, R. N.

Baker, D. E.

Bardo, R. D.

Bardo, R. D.

Bardo, R. D.

Barker, M. A.

Barlett, R. H.

9.1260

7.0976

8 1131

8.0168

9.0537

9.0265

7.0986

9.0363

7.0216

9.1284

9.0972

3.0396

5.0047

6.0183

8.0159

8.0151

8.0815

8.0892

9.0506

9.0842

7.0050

6.0389

5.0351

8 1126

3.0205

8.0151

8.0159

9.0906

9.0293

7.0325

8.1045

9.0133

9.0879

4.0014

7.0678

9.1070

9.0806

9.0972

7.0093

8.0855

9.0235

8.0262

6.0755

Name Sy.Page

Basset, J. F.

BatheIt, H.

Baudin, G.

Bauer, P,

Bauer, P.

Bauer, P.

Bauer, P.

Baute, J.

Baute, J.

Bdzil, J. B.

Bdzil, J. B.

Bdzil, J. B.

Bean, C. M.

Beard, B. C.

Beatrix, P.

Beauregard, R.

Becksted, M, W

Becksted, M. W.

Becuwe, A.

Bedoch, J. P.

Beedham, K.

Beitel Jr., F. P.

Belanger, C.

Beianger, C.

Belcher, R. A.

Belcher, R. A.

Belcher, R. A.

Belgaumkar, B. M.

Belmas, R.

Benhaim, P.

Benjamin, K. J.

Benjamin, K. J.

Benjamin. K. J.

Bennet, A. L.

Berke, J. G.

Berke, J. G.

Bernard, S.

Bemecker, R. R.

Bemecker, R. R.

Bemecker, R. R.

Bernecker. R, R.

Bemecker, R. R

Bemecker, R. R.

8.0262

8.0577

9.1371

7.0768

8.0762

90925

9.0933

8.0521

8.0751

6.0352

9.(172(1

9.0773

3.0001

9.0897

4.0527

3.0584

6.0258

7.01’$3

91008

913715 o~79

9.0585

8.0361

9.1480

7.0678

9.08319 l~js

6.0267

9 \070

6.0195

8 1139

9.1460

91489

2.025 I

5.0089

5.0237

90489

6.0426

70119

7.0843

8 (]65S

8.0881

9.0354

9.?

Name Sy.Page

C. Author Index (Continued)

Name Sy.Page Name Sy.Page

.

.

Bernier, H.

Bernstein, D.

Bhasu, V. C. Jyothi

Bi Zhu

Bines, A.

Bird, R.

Bjarnholt, G.

Bjarnholt, G.

Bjamholt, G.

Bjamholt, G.

Blais, N. C.

Bhus, N. C.

Blake, T. G.

Blommer, E. J.

Bloom, G.

Bloom, G.

Bloomquist, D. D.

Blake, O.

Boat, R.

Boggs, T. L.

Boggs, T. L.

Boggs, T. L.

Bo~sard, F.

Bongram, P.

Bonthoux, F.

Bordzilovsky, S. A.

BordzdovsLy, S. A.

Bordzilovsky, S. A.

Borgmdt, F. G.

Borisov, A. A.

Borisov, A. A.

Boslough, M. B.

Bouchon, H.

Bounrmnes, R.

Boume, N. K.

Bo\vden, F. P,

Bo\vman, A. L.

Bo\vser, M.

Boyd, T. J,

Boyd, T, J.

Boyd, T. J.

Boyer, L. R.

Boyle, V. M.

Boyle, V, M.

Boyle, V. M.

Boyle. V. M,

4.0381

3.088

9.1276

8.0093

9.1404

8.1035

5.0115

6.0510

6.0540

8 1069

8.0701

9.0953

2.0711

7.0299

8.0003

8 1045

7.1004

9.0003

6.0729

7.0216

8.0934

9.0363

7.1010

8.0159

7.0408,

7.0362

8.0143

8.0196

6.0389

6.0250

7.0435

9.1199

4.0527

7.0768

9.0869

2.0561

7.0479

2.0157

2.0136

2.0151

4.0639

9.1295

3.0520

4.0241

5.0?51

6.0011

Boyle, V. M.

Boyle, V. M.

Boyle, V. M.

Boyle, V. M.

Braconnier, J. C.

Braithwaite, M.

Brandon, W. W.

Brazen, N.

Breithaupt, D.

Breithaupt, R. D.

Breithaupt, R. D.

Brei[haupt, R. D.

Brill, T. B.

Brinkley, S. R.

Britt, A. D.

Brochet, C.

Brochet, C.

Brochet, C.

Brochet, C.

Brochet, C.

Brochet, C.

Broom, V. C.

Brossard, J.

Brosse, J. M.

Brown, B.

Brown, B.

Bro\vn, W. Byers

Brown, W. Byers

Brun, L.

Brunauer, S.

Brush, P. J.

Bugriut, F.

Bukiet, B. G.

Buntain, G. A.

Burcat, A.

Burro\vs, K.

Burt, M. W. G.

Burton, J. T. A.

Busco, M.

Bussell, T. J.

Butcher, A. G.

Butcher, B. M.

Butler, P. B.

Butler, P. B.

Cachia, G. P.

Cachia, G. P.

7.0906

9.0003

9.0897

9.1460

8.0337

9.0513

3.0822

9.1131

8.0613

9.0133

9.0525

9.1378

9.0228

1.0072

8.0734

5.0041

6.0124

7.0583

7.0768

8.0425

8.0762

4.0462

5.0041

7.0965

7.0256

7.0299

8.0770

9.0513

9.0757

1.0003

9.0228

9.0489

9.0751

9.1037 ‘,6.0590

6.0625

8.1035

7.0759

5,0513

9.1404

7.0143

4.0295

8.0962

9.0906

3.0001

4.0512

Cady, H. H.

Calzia, J.

Camarcat, N.

Cameron, I. G.

Campbell, A. W.

Campbell, A. W.

Campbell, A. W.

Campbell, A. W.

Campbell, A. W.

Campbell, A. W.

Campbell, A. W.

Campbell, A. W.

Campbell, A. W.

Campbell, A. W.

Campbell, A. W.

Campos, J.

Capellos, C.

Carabin, H.

Carion, N.

Carion, N.

Cation, N.

Carion, N.

Carlson, D. W.

Carlson, D. W.

Carlson, L. A.

Cannel, Y.

Carpenter, J. H.

Carper, W. R.

Castille, C.

Catalano, E.

Chaiken, R. F.

Chaiken, R. F.

Chaiken, R. F.

Chaisse, F.

Chaisse, F.

Chaisse, F.

Chaisse, F.

Chaisse, F.

Chambers, E. S.

Chan, M. L.

Chan, S. K.

Chang, L. M.

Chaudhri, M. M.

Chaudhri, M. M.

Chaudhri, M. M.

Chawla, M.

6,0700

5.0231

8.0815

4,0305

2.0136

2.0-$54

2.0478

3.0469

3.0499

6.0642

7.0566

7.0624

8.1057

9.0265

9.0537

9.0925

9.1084

5,0231

8.0151

8.0159

9.0506

9.084?

9.06?6

9.1260

6.0460

8.1126

4.0167

7.0075

9.1070

6.0214

3.0304

4.0461

6.0344

7.0602

7.0686

8.0159

9.0506

9.0757

7.0256

9.0566

7.0589

7.0175

5.0301

7.0735

9.0857

6.0325

.

.

.

.94

.

.

Name Sv.Paae

Chen Fumei

Chen, P. J.

Chen Peiqi

Cheret, R.

Cheret, R.

Cheret, R.

Cheret, R.

Cheret, R.

Cheret, R.

Cheret, R.

Cheret, R.

Cheret, R.

Cherm, H.

Cherville, J.

Cheselske, F. J.

Cheung, H.

Chevalier, Y.

Chhabildas, L. C.

Chiarito, M. A.

Chick, M. C.

. Chick, M. C.

Chick, M. C.

Chick, M. C.

Chiles, W, C.

Chiles, W. C.

Chiles, W. C.

Chiles, W. C.

Chilvers, D. K.

Chilvers, D. K.

Chirat, R.

Chirat, R.

Chirat, R.

Chirat, R.

Christensen, L. W.

Chung, W. K.

Chung, W. K.

Cichra, D. A.

Clairmont, A. R.

Clairrnont, A. R.

Clairmont, A. R.

Clairmont, A, R.

Clark, E. N.

Clay, R. B.

Clements, R. E.

Cobum, M. D.

Coffey, C. S.

9.0816

6.0379

9.014.2

4.0078

5.0031

5.0041

5.0567

7.0602

7.0686

8.0425

8.0815

9.0246

9.1271

7.0065

4.0461

6.0729

4.0527

8.0274

8.0645

4.0349

7.0352

8.0318

9.1404

6.0664

6.0723

8.0422

9.1335

6.0625

7.0678

7.0703

8.0521

8.0751

9.0489

6.025S

7.0343

8.0805

9.0633

6.0426

7,0119

7.0843

8.0658

3.0833

3.0150

9.064 I

6.0460

7.0970


Name Sy.Page

Coffey, C. S.

Coffey, C. S.

Coffey, C. S.

Coffey, C. S.

Coffey, C. S.

Cole, J. E.

Colebum, N. L.

Colebum, N. L.

Colebum, N. L.

Coleburn, N. L.

Coley, G. D.

Coley, G. D.

Coley, G. D.

Coley, G. D.

Conner, J.

Cook, M. A.

Cook, M. A.

Cook, M. A.

Cook, M. A.

Cook, M. A.

Cook, M. D.

Cook, M, D.

Cook, M. D,

Coon, C. L.

Cooper, J.

Cooper, J. C.

Cooper, P. W.

Costantino, M. S.

Courtney-Pratt, J. S

Courtney-Pratt, J. S

Cowan, R. D.

Cowperthwaite, M.

Cowperthwaite, M.

Cowperthwaite, M.

Cowperthwaite, M.

Cowperthwaite, M.

Cowperthwaite, M.

Cowperthwaite, M.

Cowperthwaite, M.

Cowperthwaite, M.

Cowperthwaite, M.

Cowperthwaite, M,

Cowperthwaite, M.

Cowperthwaite, M.

Cox, M.

Coyne, P, J.

8.0062

8.0725

“9.0058

9.0897

9.1243

7.0164

3.0761

4.0240

5.0523

5.0581

6.0290

7.0017

7.0278

8.0380

8.0262

2.0500

2.0519

2.0733

3.0150

3.0184

8.0827

9.1027

9.1441

7.0940

9.0197

2.0157

9.0379

9.1310

2.0168

2.0547

2.0383

4.0502

5.0427

6.01.62

6.023’1

6.0786

7.0225

7.0466

7.0498

7.1072

8.0111

8.1025

9.0089

9.0388

7.0624

8.0645

Name Sy.Page

Craig, B. G.

Craig, B. G.

Craig, B. G.

Craig, B. G.

Cramer, J. P.

Crane, S. L.

Crawford, P. C.

Cromer, D. T.

Crosnier, J.

Crouch, L. D.

Cruysberg, E. E. A.

Cudak, C. A.

Cullen, R. E.

Cumrning, I. G.

Curtis, W. D.

Damamme, G.

Damamme, G.

David, F.

David, F.

Davidova, O. N.

Davidson, N.

Davies, F. W.

Davies, F. W.

Davis, L. P.

Davis, W. C.

Davis, W. C.

Davis, W. C,

Davis, W. C.

Davis, W. C.

Davis, W. C.

Davis, W. C.

Davis, W. C.

Davis, W. C.

Davis, W. C.

Davis, W. C.

Davis, W. C.

Davis, W. C.

de Beaumont, P.

de Longueville, Y.

de Longueville, Y.

de Longueville, Y.

de Longueville, Y.

de Longueville, Y.

de Longueville, Y.

de Luca, L.

Deal, W. E.

4.0084

5.0321

8.0228

9.0573

6.0466

9.1543

9.0025

8.0839

4.0627

9.0798

6.0299

8.0962

2.0266

2.0601

7.0466

7.0634

7.0641

4.0381

5.0567

9.0724

2.0216

6.0389

6.0740

7.(1075

3.0469

3.0499

4.0084

5.0003

5.0013

5.0599

6.0637

6.0664

7.0531

7,0958

8.0422

8.0785

9.1335

5.0547

6.0105

7.0408

7.0540

7.056CJ

8.0596

91371

6.02S1

2.03?7

.95


Name Sv.Paae

Deal, W. E.

Deal, W. E.

Deal, W. E.

Deffet, L.

Dcfoumeaux, M.

Dehn, J. T.

Delter, J. S.

Delclos, A.

Delclos, A,

Delclos, A,

Delpuech, A. E.

Delpuech, A. E.

Delpuech, A. E.

Demslce, D.

Deneuville, P,

Deneuville, P.

Deneuville, P.

Deng Quan-nong

Derr, R. L.

Dernen, J. C.

Desoyer, J. C,

DeVost, D. F.

Dewey, J. M.

De\vey, J. M.

Dick, J. J.

Dick, J. J.

Dickson, P. M.

Dietzel, R. W,

Dietzel, R. W.

Dimas, P.

Dinegar, R. H.

Dmg Jing

Ding Jing

Ding Jing

Ding Jing

Ding Jing

Ding Jing

Ding Jing

Doherty, R. M.

Doherty, R. M.

Dold, J. W,

Dong I-Iaishan

Donguy, P.

Dorey, R. C.

Dorough, G. D.

Dorough, G. D,

3.0386

4.0321

9.1543

4.0156

5.0457

8.0602

9.0626

7.0560

8.0902

9.1008

7.0065

8.0847

9.0172

9.1131

7.0151

7.0408

7.0540

8.0093

7.0216

7.0151

5.0403

9.1243

1.0009

2.0612

7.0620

9.0683

9.1100

6.0455

8.0485

9.1076

6.0460

7.0795

8.0083

8.0093

8.0440

9.0077

9.0252

9.0879

9.0626

9.0633

9.0219

9.0995

7.0695

7.0075

3.0738

4.0477

Name Sy.Page

Dorsey, T. M.

Dorsey, T. M.

Downs, D. S.

Dremin, A. N.

Dremin, A. N.

Dremin, A. N.

Dremin, A. N.

Dremin, A. N.

Dremin, A. N.

Drimmer, B. E.

Drimmer, B. E.

Drolet, J. F.

Du Plessis, M. P.

Duff, R. E.

Duff, R. E.

Dufort, S.

Dufort, S.

Dunand, M.

Duvall, G. E.

Dyer, A. S.

Dyer, A. S.

Dyer, A. S.

Dyer, A. S.

Eadie, J,

Eckstein, A.

Eden, G.

Eden, G.

Eden, G.

Eden, G.

Eden, G.

Eden, G.

Edwards, D. J.

Edwards, D. J.

Edwards, J. C.

Eichler, T. V.

Eidelmcm, S.

Ek, S.

Elban, W. L.

Elban, W. L.

Elban, W. L.

Elban, W. L.

Elban, W. L.

Elliot, L. A.

Elson, R. E.

Engelke, R.

Engelke, R.

8.1139

9.1489

6.0390

5.0399

6.0029

6.0143

7.0789

8.0678

9.0724

3.0706

3.0761

8.0361

8.0390

2.0343

4.0198

8.0847

9.1271

9.0933

4.0248

5.0279

5.0291

7.1040

8.0211

4.0399

7.0721

4.0573

5.0467

6.0477

7.0678

9.0831

9.1253

5.0413

6.0766

6.0344

5.0313

6.0590

6.0272

7.0843

7.0976

8.0645

8.0725

9.1260

4.0316

6.0466

6.0642

9.0039

Name Sy,Page

Engelke, R.

Enig, J. W.

Enig, J. W.

Enig, J. W.

Enig, J. W.

Erickson, K. L.

Erickson, L. M.

Erickson, L. M.

Erickson, L. M,

Erickson, L. M.

Erickson, L. M.

Erikson, T. A.

Erkman, J. O.

Erknxtn, J. O.

Erkman, J. O.

Erkman, J. O.

Erkman, J. O.

Ermolaev, B. S.

Ermolaev, B. S.

Erskine, D. J.

Ervin, L. H.

Ervin, L. H.

Evans, M. W.

Evans, M. W.

Eyring, H.

Fagtm, P.

Fahrenbruch, A. L.

Fair, H. D.

Fanget, A.

Farag, S. A.

Farley, W. E.

Fauquignon, C.

Fauquignon, C,

Fauquignon, C.

Fauquignon, C.

Feng, K. K.

Feng, K. K.

Ferrn, E. N.

Fickett, W.

Fickett, W.

Fickett, W.

Fickett, W.

Field, J. E.

Field, J. E.

Field, J. E.

Field, J. E.

9.0657

3.0534

4.0395

5.0099

6.0570

9.1140

7.1062

8.0003

8.095 I

8.1045

9.0112

3.0024

3.0253

4.0277

5.0477

6.0426

6.0766

6.0250

7.0435

9.0670

5.0251

6.0003

4.0359

5.0089

1.0093

2.0151

4.0213

6.0390

9.1047

6.0502

9.1131

4.0039

4.0381

5.0361

6.0105

7.0343

8.0805

9.1427

2.0383

5.0003

7,0448

9.0730

5,0301

7.0024

8.0635

9.0869

.

.

.

.

96.

Name Sv.Paae



Field, J. E,

Field, J. E.

Field, J. E.

Flfer, R. A.

Filler, A. S.

Filler, W. S.

Filler, W. S.

Finger, M.

Finger, M.

Finger, M.

Finger, M.

Finger, M,

Finger, M,

Finger, M.

Flaugh, H. L.

Fleming, K. A.

Foan, G. C. W.

Foan, G. C. W.

Forbes, J. W.

Forbes, J. W..

Forbes, J. W,

Forbes, J. W.. Forbes, J. W.

Forbes, K.

Forest, C. A.

Forest, C. A.

Forest, C. A.

Forest, C. A.

Fortov, V. E.

Fortova, T. N.

Fosse, C.

Foster, J.

Fowles, G. R.

Frank, A. M.

Frankel, M. J,

Frankel, M. J,

Freund, H. V.

Frey, R. B.

Frey, R. B,

Frey, R. B.

Frey, R. B.

Frey, R. B.

Frey, R. B.

Frey, R. B.

Frey, R. B,

Frey, R. B,.

9.0886

9.1100

9.1276

7.0164

2.0733

6.0777

8.0207

4.0003

5.0137

5.0503

6.0710

6.0729

7.0940

8.1018

7.0566

8.1035

7.0278

9.0123

7.0308

8.0725

9.0806

9.0897

9.1235

8.0228

7.0234

7.0479

8.0052

9.0683

9.0050–-

9.0050

4.01S6-

8.0228

4.0213

9.064 I

7.0523

7.0970

6.0521

6.0011

6.0325

7.0036

7.0247

7.1048

8.0068-

8.0318

9.0003

9.1404

Fritz, J. N.

Fu Xinghai

Fu Xinghai

Fujiwara, S.

Fujiwara, S.

Fujiwara, S.

Fujiwara, S.

Fujiwara, S.

Fukatsu, 1’.

Fuller, P. J. A.

Funk, A. G.

Fyfe, R, R.

Gardner, S. D.

Gaudin, C.

Gaudin, C.

Geiger, W.

Gey, W. A.

Gibb, A. W.

Gibb, A. W.

Gibb, A. W.

Gibbons, G.

Gibson, F. C.

Gibson, F. C.

Gibson, F. C.

Gibson, F. C.

Gibson, F. C.

Gibson, F. C.

Giddings, J. C.

Gilkerson, W. R.

Gimenez, P.

Gimenez, P.

Ginsberg, M. J.

Ginsberg, M. J.

Gittings, E. F.

Glancy, B. C.

Glancy, B. C.

Glenn, J. G.

Glover, D. J.

Gohar, P.

Goldstein, S.

Goldstein, S.

Goliger, J.

Goodale, T. C.

Gem, T.

Gordon, W E.

Graham, K. J.

5.0447

8.0089

9.1360

5.0267

6.0133

6.0450

8.0993

9.0621

9.0640

4.0290

3.0184

6.0466

4.0154

7.0540

7.0560

6.0521

3.0813

8.0409

9.0853

9.1364

8.0294

1.0012

2.0157

2.0281

3.0436

4.0117

4.0412

2.0404

2.0216

8.0596

9.1371

7.0385

9.0537

4.0373

9.0341

9.1260

9.1284

8.0725

9.1271

7.1016

8.0979

6.0195

6.0231

6.0390

4.0179

91295

Graham, R. A.

Graham, R. A.

Graham, R. A.

Green, L. G.

Green, L. G.

Green, L. G.

Green, L. G.

Green, L. G.

Green, L. G.

Green, L, G.

Green, L. G.

Green, L. G.

Green, L. G.

Green, N. J. B.

Greifer, B.

Greiner, N. ‘R.

Greiner, N. R.

Greiner, N. R.

Grief, D.

Griffiths, N.

Groocock, J. M.

Groothtrizen, T. M.

Gross, S. B.

Groux, J.

Groux, J.

Guidry, M.

Guiguis, R. H.

Gunger, M.

Gunn, S. R.

Guo Yuxian

Guo Yuxian

Guri, G.

Gurton, O. A. J.

Guy, L. R,

Gvishi, M.

Gyton, R.

Hackett, A.

Haeffele, B.

Hagan, J. T.

Halleck, P. M.

Hallouin, M.

Hallquist, J. O.

Hallquist, J. O.

Halpin, W. J.

Hampton, L. D.

Han Chengbung

4.0222

5.0369

9.1529

4.0086

4.0477

6.0755

7.0256

7.0273

7.0887

8.0284

8.0587

9.0670

9.0701

9.1193

2.0281

8.0715

9.0953

9.1170

8.0380

4.0462

2.0529

6.0299

7.0843

8.0431

9.1217

6.0710

6.0502

8.0228

4,0167

8.1011

9.0554

9.0506

2.0582

7.0107

8.1126

6.0625

8.0187

7,0721

7.0735

6.020

5.0403

7.0488

8.0951

4.0222

2.0620

80567

.97


Name Sy.Page

Han Chengbang

Hannaford, C. E,

Hantel, L. W.

Hardesty, D, R.

Hardy, J. R.

Hardy, J. R.

Harlan, J. G.

Hart, .S.

Hartley, J. E.

Harvalik, Z. V.

Haslcins, P. J.

Haskins, P. J.

Haskins, P. J.

Haskins, P. J.

Hasmirn, E.

Hatt, D. J.

Hattori, K.

Hauver, G. E.

Httuver, G. E.

Ha\vkins, A.

Hawkins, S. J.

Hay, J. E.

Hay, J. E.

Hay, J, E.

Hay, J. E.

Hay, J. E.

Hayes, B.

Hayes, B.

Hayes, B.

Hayes, B.

Hayes, B.

Hayes, B.

Hayes, D. B.

Hayes, D. B.

Hayes, D. B.

He Xm-ichu

Held, M.

Held, M.

Held, M.

Held, M,

Helm, F, H,

Helm, F H.

Helm, F. H.

Helm, F, H.

Hemsmg, W. F.

Hermes, R.

9.09’$7

9.1076

5.0599

6.0047

7.0777

8.0864

7.0930

4.0047

4.0538

3.0842

8.0211

8.0827

9.1027

9.1441

8.1126

7.0352

9.0640

3.0241

5.0387

5.0034

7.0759

4.0412

5.0081

5.0559

6.0115

7.0373

3.0139

4.0595

5,0447

6.0710

6.0729

7.1029

6.0076

6.0668

6.0748

8.0567

6.0225

7.0751

8.0330

9.1416

6.0710

6.0729

7.09’$0

9.0025

8.0468

9.1170

Name Sy.Page

Hershkowitz, J.

Hershkowitz, J.

Hershkowitz, J.

Hershkowitz, J.

Hershkowitz, J.

Hess, W. R.

Heuze, O.

Heuze, O.

Heuze, O.

Heybey, W. H.

Hicks, A. N.

Hlkita, T.

Hlkita, T.

Hillyer, R. M.

Ho, S. Y.

Hofer, W. W.

Hoffsommer, J. C.

Holland, T. E.

Holmberg, R.

Holmes, N. C.

Holmes, W. I.

Honcia, G.

Honodel, C.

Hooper, G.

Horie, Y.

Homig, H. C.

Homig, H. C.

Homig, H. C.

Homig, H. C.

Hoskin, N. E.

Hoskin, N. E.

Hoskin, N. E.

Houston, E.

Howe, P. M.

Howe, P. M.

Howe, P. M.

Howe, P. M.

Howe, P. M.

Hrdirm, D. J.

Hsieh, T

HU Donti

Huan S1,,

Huan .%.

Huang Llhong

Hwtng, Y. K.

Huang, Y. K.

4.0168

6.0439

7.0175

7.0898

7.0914

3.0042

8.0762

9.0925

9.0933

2.0295

6.0551

8.0558

9.0939

4.0449

9.1052

6.0755

8.0725

2.0454

6.0540

9.0190

5.0279

6.0521

7.0425

7.0759

4.0248

4.0003

5.0137

5.0503

6.0710

4.0014

5.0501

7.0811

2.0343

6.0011

7.1048

7.1055

8.0294

8.1150

9.0972

9.0329

8.0093

9.0077

9.0252

9.0947

7.1055

8.0307

Name Sy.Page

Huang, Y. K.

Huang Zhengping

Huang Zhengping

Hubbard, P, J.

Hubbard, P. J.

Hubbard, P. J.

Hubbard, P. J.

Hudgins, H. E.

Huiling, L.

Hull, J. A.

Humphrey, J.

Huntley, J. M.

Hurwitz, H.

Hurwitz, H.

Hutchinson, C. D.

Hutchinson, C. D.

Hutchinson, C. D.

Igel, E. A.

Igel, E. A.

Iida, M.

Iida, M.

Ingram, G. E.

Ishiokawa, N.

Iwata, L.

Jackson, R. K.

Jackson, R. K.

Jacobs, S. J.

Jacobs, S. J.

Jacobs, S. J.

Jacobs, S. J.

Jacobs, S. J.

Jacobs, S. J.

Jacques, L.

Jacquesson, J.

Jacquesson, J.

Jacquesson, J.

Jaffe, I.

James, E.

James, E.

James, E.

James, E.

James, E.

James, E.

James, H. R.

James, R. M.

Jameson, R. L.

8.0943

8.0083

8.0440

7.1040

8.0211

8.0262

9.1322

7.0175

8.0440

2.0136

7.0425

9.0886

3.0205

6.0528

8.0211

8.1105

9.0123

2.0439

7.0865

8.0993

9.0621

5.0369

9.0621

9.1084

6.0653

6.0755

1.0052

2.0358

3.0784

5.0413

6.0305

7.0970

5.0457

4.0627

5.0403

6.0151

3.0584

2.0119

3.0327

4.0086

7.0256

7.0887

8.0284

9.1441

6.0489

3.0120

.

●

.

.

.

98

Name Sy.Page

.

.

Jameson, R. L.

Jameson, R. L.

Jensen, R. C.

Jerberyd, L.

Jia Quansheng

Jiao Qinjie

Jing Fu-Qian

Johansson, C. H.

Johnson, C. B.

Johnson, C. D.

Johnson, E. G.

Johnson, J. D.

Johnson, J. D.

Johnson, J. N.

Johnson, J. N.

Johnson, J. O.

Jones, A. G.

Jones, E.

Jones, E.

Jones, E. C..

Jones, H. D.

Jones, H. D.. Joyner, T. B,

Jun Wung Lee

Jung, R. G,

Jungst, R. G.

Junk, N. M.

Kaharri, M.

Kamal, M. M.

Kamegai, M.

Kamlet, M. J.

Kamlet, M. J.

Kamlet, M. J.

Kamlet, M. J.

Kamlet, M. J.

Kanel, G. I.

Kang, J.

Kang Shufang

Ki.mg Shufong

Kantrowitz, A.

Kapila, A. K.

Kamkhanov, S. M.

Karakhanov, S. M.

Karakhanov, S. M.

Karo, A, M.

Karo. A. M.

4.0241

5.0034

7.0299

7.0043

9.0816

8.0083

7.0826

4.04.35

7.1062

5.0047

4.0584

8.0531

9.0417

7.1016

8.0052

6.0020

9.0123

2.0571

2.0601

7.0050

7.0716

9.0461

3.0050

9.0471

5.0191

9.1510

4.0092

6.0710

6.0502

5.0477

3.0671

6.0305

6.0312

7.0084

7.0952

9.0050

9.0906

9.0947

8.0567

1.0079

9.0219

7.0362

8.0143

8.0196

7.0777

8.0864


Name Sy.Page

Kassel, C.

Kate, Y.

Kate, Y.

Kate, Y.

Kate, Y.

Kate, Y

Kate, Y.

Keefe, R. L.

Keefe, R. L.

Kegler, W.

Kendrew, E. L.

Kendrewj E. L.

Kennedy, D. L.

Kennedy, J. E.

Kennedy, J. E.

Kennedy, J. E.

Kennedy, J. E.

Kennedy, J. E.

Kennedy, M.

Kenney, I.

Kenney, J.

Kerihuel, M. T.

Kerley, G. I.

Kerley, G. L

Kerr, I. D.

Kershner, J. D.

Kershner, J. D.

Kershner, J. D.

Keyes, R. T.

Keyes, R. T.

Keyes, R. T.

Keyes, R. T.

Khasainov, B. A.

Khasainov, B. A.

Khrapovsky, V. E.

Kim, K.

Kim, K.

Kim, K.

Kim, K.

Kinaga, K.

Kincaid, J.

Kinelce, J. H.

King, A. J.

Kinney, J. H.

Kipp, M. E.

Kipp, M, E.

7.0965

6.0124

7.0583

7.0768

8.0558

9.0640

9.0939

7.0143

7.0265

4.0496

3.0202

3.0574

9.1224

4.0449

5.0435

6.047

6.068

6.0379

9.1351

9.1019

9.1019

9.0506

8.0540

9.0443

9.1351

7.0479

8.042

9.0693

2.0733

3.0150

3.0202

3.0357

6.0250

7.0435

6.02’50

7.0843

8.0926

9.0329

9.0593

3.0813

7.0887

5.0533

6.0258

9.0868

7.0394

7.0608

Name Sy.Page

Kipp, M. E.

Kipp, M. E.

Kipp, M. E.

Kipp, M. E.

Kirby, I. J.

Kirby, I. J.

Kirkham, J.

Kirkwood, J. G.

Kirkwood, J. G.

Kirkwood, J. G.

Kirkwood, J. G.

Kistiakowsk--, G. B.

Kistiakowsky, G. B.

Kistiakowsky, G. B.

Kistiakowsky, G. B.

Klee, C.

Kleinhanss, H.R.

Klimenko, V. Yu.

Klimenko, V. Yu.

Klimenko, V. Yu.

Kober, E. M.

Kodde, H. H.

Kolodney, K.

Kooker, D. E.

Kooker, D. E.

Komhauser, M.

Komhauser, M.

Korotkov, A. I.

Korotkov, A. I.

Kosireva, [. Y.

Kot, C. A.

Kot, C. A.

Kovacic, S. M.

Krall, A. D

Kramer, P. E.

Kramer, P. E.

Kravtsov, V. V.

Krier, H.

Kroh, M.

Kumar, M.

Kuo, K. K.

Kurrle, J. E.

Kury, J. W.

Kury, J. W.

Kury, J. W.

Ku~. .I W

8.0035

8.0274

9.0?(19

9,1510

8.0176

8.0187

3.0001

1.0071

10107

2.0312

2.0424

I 0045

1 UI05

2.0187

2.0198

7.0336

9.0066

7.0789

8.0678

9.0724

91185

9.0560

91084

70198

9.0306

70834

9.1451

6.0250

7.0435

8.0678

5.0313

6.0336

70186

9.034 I

6.0755

7.0425

6.W36

8.0962

8.1131

7.0186

7,0186

5.0503

3.0738

-10003

50 [37

x (1(,13

.

Name Sy.Page

Kury, J. W.

Kury, J. W.

Kuty, J. W.

Kusabov, A. S.

Kusakabe, M,

Kusakabe, M.

Kusakabe, M.

Kusakabe, M,

Kwak, D.

Kydd, P. H.

Kyselka, C.

Lamboum, B. D.

Lamboum, B. D.

Lamboum, B. D.

Lambourn, B. D.

Ltrmbourn, B. D.

Lambourn, B. D.

Lambourn, B. D.

Lambourn, B. D.

La.mbourn, B. D.

Lamboum, B. D.

Lamboum, B. D.

Lambrakos, S. G,

Lanzerotti, M. Y. D.

Lanzerot[l, M. Y. D.

Larson. T. E.

La\rn, H. R.

Lederer, R. A.

Lee, E. L.

Lee. E. L.

Lee, E. L.

Lee, E. L.

Lee, E. L.

Lee. E. L.

Lee, E, L.

Lee. E. L.

Lee, E. L.

Lee, E. L.

Lee, E. L.

Lee, E. L,

Lee. E. L.

Lee, E. L.

Lee, E. L.

Lee. J.

Lee, L. M.

Lee, L M

8.0902

9.0025

9.1378

5.0105

5.0267

6.0133

6.0450

8.0993

5.0119

2.0187

4.0404

4.0052

4.0142

4,0538

5.0501

6.0477

6.0489

6.0561

6.0625

7.0811

8.0778

9.0784

9.0713

8.0243

9.0918

9.1076

9.0123

6.0668

4.0003

5.0137

5.0331

5.0503

6.0214

6.0710

6.0729

7.0256

7.0517

7.0887

8.0284

8.0587

8.0613

8.0914

9.0280

9.0573

7.0416

7.0865


Name Sy.Page

Lee, L. M.

Lee, P. R.

Lee, R. J.

Lee, R. S.

Lee, R. S.

Lee, R. S.

Lee, R. S.

Lee, R. S.

Lee, R. S.

Lee, R. S.

Lee, R. S.

Leeuw, M. W.

Legrand, J.

Legrand, N.

Leibundgut, F.

Leiper, G. A,

Leiper, G. A.

Leiper, G. A.

Leiper, G. A.

Lemar, E. R.

Leone, Capt. N.

Leopold, H. S.

Lepie, A. H.

Leroy, M.

Leroy, M.

Leslie, W. B.

Lethaby, J. W.

Lethaby, J. W.

Lewis, B.

Leygonie, J.

Li Huiling

Liang Yunming

Liddiard, T. P.

Liddiard, T. P-

Liddiard, T. P,

Liddiard, T. P.

Liddiard, T. P.

Liddiard, T. P.

Liddiard, T. P.

Liddiard, T. P,

Liddiard, T. P.

Lind, C. D.

Ling, R. C.

Listh, O.

Lobanov, V. F.

Lobanov, V. F.

9.1529

7.1040

9.0396

6.0653

6.0755

7.0425

7.0466

7.1062

8.0003

8.1045

9.0798

8.0710

5.0567

7.0695

8.0399

8.0176

8.0187

9.0197

9.1224

9.0806

4.0404

5.0339

9.1295

8.0815

9.0506

6.0455

4.0014

3.0573

1.0043

5.0547

8.0440

8.0083

3.0706

3.0761

4.0214

4.0240

4.0487

7.0308

7.0970

8.0725

9.1235

9.0566

3.0042

6.0204

7.0362

8.0196

.

Name Sy.Page

Louie, N, A.

Loupias, C.

Lownds, C. M.

Lu, B. C.-Y.

Lu, B. C.-Y.

Lu, P.

Ludwig, D.

Ludwig, D.

Lundborg, N.

Lundborg, N.

Lungenstrass, F,

Lyman, O. R.

Macek, A.

Macintyre, I. B.

Mader, C. L.

Mader, C. L.

Mader, C. L.

Mader, C. L.

Mader, C. L.

Mader, C. L.

Mader, C. L.

Mader, C. L.

Mader, C. L.

Mal’kov, I. Yu.

Mala, J.

Mala, J.

Mala, J.

Malin, M. E.

Malin, M. E.

Malin, M. E.

Mallory, H. D.

Malyrenko, S. I.

Manson, N.

Mark, P.

Marlow, W. R.

Marlow, W. R.

Marshall, E. F.

Marshall, W. W.

Marshall, W. W.

Mason, C. M.

Mason, C. M.

Mason, C. M.

Mason, C. M.

Matsui, H.

Maurin, C.

Mautz, C. W.

6.0682

9.1047

8.0390

7.0343

8.0805

8.0460

6.0225

7,0336

4.0176

4.0432

9.0066

8.1080

3.0606

8.0318

3.0725

4.0394

5.0177

6.0405

7.0479

7.0669

8.0042

8.0979

9.0693

9,0407

7.0540

7.0560

8.0625

2.0136

2.0454

2.0478

2.0358

9.0050

5.0041

6.0390

4.0426

9.1253

5.0321

5.0185

5.0247

1.0012

2.0157

2.0281

3.0436

8.0168

7.0131

2.0478

.

.1

I.

I00

Name Sy.Page



.

?

Mazzella, A.

McAfee, J, M,

McCandless, P.

McDonnel, J. L.

McEachem, D. M.

McFadden, D. L.

McFadden, D. L.

McGuire, R. R.

McGuire, R. R.

McGuire, R. R.

McGulre, R. R.

McGuire, R. R.

McGuire, R. R.

McKinney, T. L.

McKnight, C. E.

McLaren, A. C.

McMillan, C.

Mehlmtm, M. H.

Melani, G.

Menichelli, V. J... Menil, A.

Meulenbrugge, J. J.. Michailjuk, K. M.

Michaud, C.

Michaud, C.

Migault, A.

Miller, P. J.

Miller, P. J.

Miller, S.

Mishra, 1. B.

Missonier, M

Mitchell, A.

Mitchell, D. E.

Miyake, A.

Moen, 1, 0.

Mohan, V. K.

Mohan, V. K.

Mohier, J. H.

Moniz, W. B.

Monteagudo, P.

Moore, D. B.

Moore, D. S.

Moore, L. M.

Moore, P. W. 1.

Mon. N.

Mon. N.

5.0351

9.0265

9.0190

4.0003

4.0126

8.1080

9.1460

6.0214

6.0710

7.0056

7.0940

8.0003

8.1018

9.1037

3.0635

2.0561

8.0613

8.0864

6.0325

6.0612

7.1010

9.0083

7.0789

7.0065

7.0965

4.0627

9.0341

9.0498

9.1131

9.1084

7.064.1

8.0587

6.0748

9.0560

9.1364

7.0373

9.1276

7.0865

8.0734

7.0151

3.088

9.0180

9.1529

6.0489

8.0558

9.0640

Mori, N.

Moritani, A.

Morris, C. E.

Morrison, R. B.

Morvan, J.

Mottet, A. L.

Moulard, H.

Moulard, H.

Moulard, H.

Moulard, H.

Muller, G. M.

Munson, D. E.

Murphy, M. J.

Murry, W. L.

Myers, T. F.

Naiman, E.

Nalcayama, Y.

Namenson, A. I.

Nanut, V.

Napadensky, H. S.

Napadensky, H. S,

Napadensky, H. S.

Napadensky, H. S.

Napadensky, H. S.

Neal, T. R.

Needham, C. E.

Nicholls, J. A.

“Nidick, E. J.

Nikowitsch, P.

Nikowitsch, P.

Nilsson, H.

Nilsson, H.

Nunziato, J. W,

Nunziato, J. W.

Nunziato, J. W.

Nunziato, J. W.

O’Brien, J. F.

Ockert, K. F.

Ockert, K. F.

Ockert, K. F.

Olinger, B.

Oppenheim, A. K.

Oppenheim, A. K.

Oran, E. S.

Orlow, T.

Omellas, D. L.

9.0939

8.0168

6.0396

2.0266

5.0429

5.0067

6.0105

7.0316

8.0902

9.0018

3.088

4.0295

9.0525

4.0555

7.0914

8.0460

9.0621

7.0050

9.0098

3.0396

3.0420

4.0473

5.0313

6.0336

6.0602

5.0487

2.0266

6.0755

6.0225

7.0751

9.0162

9.1151

6.0047

7.0374

7.0608

9.0293

4.0239

3.0822

4.0096

4.0102

6.0700

5.0119

6.0502

9.0713

3,0226

4,0003

Omellas, D. L.

Omellas, D. L.

Omellas, D. L.

Omellas, D. L.

Omellas, D. L.

Ostmark, H.

Ostmark, H.

Ostmark, H.

Otani, G.

Ouyang Denghuan

Owens, F. J.

Pace, M. D.

Pace, M. D,

Paisley, D. L.

Palmer, S. J. P.

Palmer, S. J. P.

Pandow, M. L.

Pandow, M. L.

Parker, N. L.

Parker, N. L.

Parker, N. L.

Parlin, R. B.

Parlin, R. B.

Parry, M. A.

Parry, M. A.

Parsons, G. H.

Partom, Y.

Partridge, W. S.

Pasman, H. J.

Pastine, D. J.

Pastine, D. J.

Paszek, J.

Paul, S.

Pearson, J. C.

Peek, H. M.

Pelletier, P.

Peng Guoshu

Penn, L.

Persson, A.

Persson, A.

Persson, G.

Persson, P. -A.

Persson, P. -A.

Persson, P. -A.

Persson, P. -A.

Persson, P. -A.

4.0167

6.0214

7.0940

9.1162

9.1310

8.0473

9.0162

9.1151

9.0190

9.0142

8.0742

8.0734

9.0987

9,1110

8.0635

9.0886

4.0096

4.0102

6.0653

7.1062

8.0613

1.0093

2.0404

9.0886

9.1100

9.1284

7.0506

?.0733

6.0299

6.0305

7,0523

3.0520

7.0686

4.0289

2.0231

8.0361

8.1011

6.0729

7.0043

8.0985

6.0414

4.0602

5.0115

5,0153

6.041-f

S 0985

10!

Name Sy.Page

Persson, P. -A.

persson, P. -A.

Peters, W. C.

Petrone, F. J.

Petrone, F. J.

Pettit, D. R.

Peyrard, M.

Peyre, C.

Peyre, C.

Philipart, D. A.

Piacesi, D.

Piacesi, D.

Pike. H. H. M.

Pilrmki, D. L.

Pilarski, D. L.

Pilcher, D. T.

Pilling, M. J.

Pimbley, G. H.

Pinegre, M.

Pinto, J. J.

Pinto, J. J.

Pirotais, D.

Pittion-Rossillon, G.

Pitts, L. D,

Plant, J.

Plomrd, J. P.

Politzer, P.

Pope, P. H.

Popolato, A.

Popolato, A.

Potriu, J.

Poulard, S,

Potvers, P. S.

Pratt, T. H.

Presles, H. N.

Presles, H. N.

Presles, H. N.

Presles, H. N.

Presles, H. N.

Pressman, Z.

Price, C. F.

Price, C. F.

Price, C. F,

Price, D.

Price. D.

Pncc. D.

9.0545

9.0573

5.0559

4.0395

5.0099

9.0683

9.0713

4.0135

4.0566

8.0447

3.0226

4.0153

4.0305

7.0906

9.1460

6.0258

9.1193

7.0479

8.0815

8.0243

9.0918

8.0337

7.0703

4.0616

4.0555

8.0337

9.0566

8.0635

4.0233

7.0566

4.0381

7.0965

9.1084

4.0102

7.0583

8.0431

8.0762

9.0925

9.0933

4.0126

7.0216

8.0934

9.0363

1.0022

5.0207

6.0426


Name Sy.Page

Price, D.

Price, J. H.

Protat, J. C.

Prouteau, F.

Prouteau, M.

Pugh, H. L.

Pujol, J.

Pujols, H. C.

Pujols, H. C.

Quidot, M.

Quirk, W.

Rainsberger, R. B.

Ramsay, J. B.

Ramsay, J. B.

Ramsay, J. B.

Ramsay, J. B.

Ramsay, J. B.

Ramsay, J. B.

Ramsay, J. B.

Ramsay, J. B.

Ramsav, J, B.

Ramsay, J. B.

Ramsay, J. B.

Randall, R. R.

Reddy, G. Om

Ree, F. H.

Ree, F. H.

Ree, F. H.

Ree, F. H.

Reed, R. P.

Reed, S. G.

Reese, B. O.

Reisler, H.

Rempel, J. R.

Renick, J. D.

Renlund, A. M.

Renlund, A. M.

Renlund, A. M.

Reynier, P.

Ribovich, J.

Ribovich, J.

Rice, J. K.

Rice, S. F.

Richter, H. P.

Rigdon, J. K.

Rdey, J, F.

9.1235

4.0290

8.0815

5.0567

4.0039

7.0075

4.0566

5.0429

8.0135

9.1217

8.0613

7.0466

3.0499

4.0084

4.0233

6.0723

7.0531

7.0566

8.0372

9.0265

9.0537

9.1427

9.1543

5.0067

9.0585

7.0646

8.0501

9.0425

9.0743

9.1529

2.0295

4.0359

9.1084

4.0266 .,

9.0545

8.0691

9.0153

9.1118

9.1070

4.0412

5.0081

7.0930

9.0190

9.1295

5.0059

6.0740

Name Sy.Page

Rinehart, J. S.

Rinehart, J. S.

Ringbloom, V.

Ritchie, J. P.

Ritchie, J. P.

Rivard, W. C.

Rivera, T.

Rivers, T.

Robertson, S. H.

Robinson, N. J.

Rogers, G. T.

Rogers, J. W.

Remain, J. P.

Remain, J. P.

Rooijers, A. J. T

Rosenberg, J. T.

Rosenberg, J. T.

Rosenberg, J. T.

Rosenberg, J. T.

Rosenberg, J. T.

Roslund, L. A.

Roslund, L. A.

Roth, J.

Roth, J.

Ryan, R. R.

Sadwin, L. D.

Sadwin, L. D.

Saint-Martin, C.

Saint-Martin, C.

Sakai, H.

Saliai, H.

Saliurai, A.

Sakurai, T.

Sakurai, T.

Samirant, M.

Samirant, M.

Samirant, M.

Sanbom, R. H.

Sanchez, J. A.

Sanders, S.

Sandstrom, F. W.

SandusLy, H. W.

Sandusky, H W,

SandusLy, H. W.

Sandustw, H. W.

Sandusky, H. W.

1.0031

3.0285

9.0626

8.0839

9.1185

5.0003

9.1014

9.1037

9.1193

7.0143

2.0547

7.0930

5.0403

6.0151

8.0710

6.0786

7.0466

7.1072

8.0111

9.0089

5.0523

5.0581

1.0057

5.0219

8.0839

3.0309

4.0092

8.0596

9.1371

8,0558

9.0939

5.0493

8.0558

9.0939

7.0139

8.0972

9.0259

5.0331

9.0545

8.0003

9.0573

7.0119

7.0843

8.0658

8.0881

9.0341

.

.

.

*

Name Sy.Page



Sandusky, H. W.

Sang Wu

Santiago, F.

Savitt, J.

Savitt, J.

Savitt, J.

Savitt, J.

Savitt, J.

Schall, R.

Schedlbauer, F.

Schedlbauer, F.

Schilperoord, A. A.

Schilperoord, A. A.

Schmidt, D. N.

Schmidt, S. C.

Schott, G. L.

Schott, G. L.

Schuler, K. W.

Schwartz, F. R.

Schwarz, A. C..

Schwarz, A. C.

Schwarz, A. C.● Schwarz, A. C.

Scott, C. L.

Scott, F. H.

Scott, F. H.

Scribner, K.

Searcy, J. Q.

Searcy, J. Q.

Seay, G. E.

Seegar, D. E.

Seely, L. B.

Seely, L. B.

Seely, L. B.

Seely, L. B.

Seely, L, B.

Segalov, Z.

Seitz, W. L.

Seitz, W. L.

Sei[z, W. L.

Sellam, M.

Sentman, L. H.

Servas, J. M,

Servas, J. M,

Servas, J. M.

Setchell, R. E.

9.1260

7.0746

8.0725

2.0620

3.0309

3.0396

3.0420

4.0404

4.0496

8.0577

9.0962

6.0371

7.0575

4.0?66

9.0180

4.0067

9.1335

5.0589

3.0833

6.0062

6.0668

7.0416

7.1024

5.0259

2.0157

4.0412

6.0466

6.0062

6.0455

3.0562

2.0711

2.0439

3.0562

4.0359

5.00s9

5.0237

8.1126

7.0385

8.0123

9.0657

8.0425

7,0721

7.0686

8.0159

9.0842

7.0394

Setchell, R. E.

Setchell, R. E.

Setchell, R. E.

Shai%ia, J.

Sharrrm, J.

Sharples, R. E.

Shaw, L. L.

Shaw, M. S.

Shaw, M. S.

Shaw, R.

Shaw, R.

Shaw, R.

Shea, J. H.

Sheffield, S. A.

Sheffield, S. A.

Sheffield, S. A.

Sheffield, S. A.

Sheffield, S. A.

Shepherd, J. E.

Shi Huisheng

Shiino, K.

Shiino, K.

Shikari, Y. A.

Short, J. M.

Shrader, J.

Shuey, H. M.

Shupe, O. K.

Shvedov, K. K.

Silvestrov, V. V

Simpson, R. L.

Simpson, R. L.

Simpson, R. L.

Sitzmann, M. E.

Sjolin, T.

Sjolin, T.

Skidmore, I. C.

Skidmore, I. C.

Skidmore, I. C.

Skocypec, R. D.

Slettevold, C.

Slie, W. M.

Smedberg, u.

Smith, C. P. M.

Smith, C. P. M.

Smith, L. C.

Smolen, J. J.

7.0857

8.0015

9.0209

8.0725

9.0897

3.0738

6.0755

8.0531

9.0452

5.0089

5.0237

6.0231

5.0351

6.0668

6.0748

7.1004

9.0039

9.0683

9.0641

9.0947

6.0450

8.0993

6.0336

7.0952

6.0740

4.0096

3.0150

6.0029

6.0036

9.0025

9.0280

9.0525

9.1162

4.04~5

5.0153

4.0014

4.0047

5.0573

9.1140

8.0003

2.0749

8.1069

5.0467

6.0477

3.0327

5.0119

Smothers, W. G.

So-young Song

Sohrii C. H.

Solomonovici, A.

Song Jialiang

Sorel, J.

Sorel, J.

Souletis, J.

Souletis, J.

Spaulding, R. L.

Spear, R. J.

Stacy, H. L.

Stacy, H. L.

‘Stadnitshenko, I. A.

Stahl, S. O.

Stanton, P. L.

Stanton, P. L.

Stanton, P. L.

Starkenberg, J.

Starkenberg, J.

Starkenberg, J.

Starlcenberg, J.

Starkenberg, J.

Starkenberg, J.

Starkenberg, J.

Starr, L. E.

Stec, D.

Steele, R. D.

Steinberg, D. J.

Steinberg, H. M.

Steinberg, H. M.

Steinberg, H. M.

Steinberg, H. M.

Steinberg, H. M.

Steinberg, H. M.

Stewart, D. S.

Stewart, D. S.

Stewart, J. R.

Stewart, R. F.

Stinecipher, M. M.

Stinecipher, M. M.

Stolovy, A.

Strange, F. M.

Strehlow, R. A.

Stresau, R. H. F.

Stresau, R. H. F.

5.0251

9.0471

8.0926

8.1126

8.1011

8.0135

8.0892

8.0431

8.0625

7.0877

9.0098

8.0123

9.0657

6.0036

4.0602

7.0865

8.0485

9.1118

7.0003

8.0307

8.1080

8.1139

9.0604

9.1460

9.1489

2.0620

8.0734

9.1014

8.0513

3.0205

3.0226

4.0027

4.0153

5.0597

6.0528

9.0730

9.0773

8.0962

8.0839

7.0801

8.0351

7.W50

4.0003

7.0721

2.0620

2.071 I

103


Name Sy.Page

Stresau, R. H. F.

Stresau, R. H. F.

Stresau, R. H. F.

Stresau, R. H. F.

Stresau, R. H. F,

Stresau, R. H. F.

Strcsau, R. H, F.

Stretz, L. A.

Stretz, L. A.

Stromberg, H. D.

Sulimov, A. A.

Sultanoff, M.

Sultanoff, M.

Sultanoff, M.

Sultanoff, M.

Sumida, W. K.

Sun Chengwei

Sun Jim

Sundararajan, R.

Swallowe, G. M.

S\vaklo\ve, G. M.

Swanson, B. I.

Swanson, B, I.

Swlt’t, D. C.

Takala, B. E.

Taliancich, A. G.

Tan Bing-Sheng

Tanaka, K.

Tanaka, K.

Tanaka. K,

Tanaka, K

Tanaka, K.

Tang, P K.

Tang, P. K.

Tao, W. C.

Tao. W. C.

Tao, W. C.

Tao. W C.

Tarver, C. M

Tarver, C. M.

Tarver, C. M.

Twver, C. M.

Tarver, C. M.

Tarver, C. M.

Tamer, C. M.

Tarver, C. M,

2.0749

3.0309

3.0396

3.0420

4.0442

4.0449

6.0068

8.0351

9.1014

5.0331

6.0250

2.0157

3.0436

3.0520

4.0117

9.0972

9.0142

9.0435

8.0635

7.0024

8.0635

8.0715

9.1019

9.0784

9,1543

9.0089

7.0826

7.0583

8.0548

8.0558

8.0993

9.0621

8.0052

9.0657

9.0641

9.0798

9.0868

9.1310

6.0231

7.0056

7.0256

7.0488

7,0993

7.1029

8.0587

8.0613


Tarver, C. M.

Tarver, C. M.

Tarver, C. M.

Tarver, C. M.

Tarver, C. M.

Tamer, C. M.

Ta~er, C. M.

Tasker, D. G.

Tasker, D. G.

Taylor, B. C.

Taylor, B. C.

Taylor, G. W.

Taylor, G. W.

Taylor, J. W.

Taylor, J. W.

Taylor, J. W.

Taylor, P. A.

Tegg, D.

Thivet, R.

Thoma, K.

Thoreen, J. L.

Thouvenin, J.

Thouvenin, J.

Thouvenin, J.

Thouvenin, J.

Thrap, R. G.

Timnat, Y. M.

Tisley, D. G.

Titov, V. M.

Titov, V. M.

Titov, V. M.

Titov, V. M.

Titov, V. M.

Tokita, K.

Tombini, C.

Tomlinson, R.

Torii, A.

Travis, J. R.

Travis, J. R.

Travis, J. R.

Travis, J. R.

Travis, J. R.

Trebinski, R.

Trevino, S. F.

Trimble, J. J.

Trimble, J. J.

8.0951

8.1045

9.0112

9.0133

9.0525

9.0670

9.0701

7.0285

9.0396

3.0267

6.0003

9.1014

9.1037

3.0077

5.0291

5.0311

8.0026

5.0089

7.0107

8.1131

9.1284

4,0135

4.0258

4.0566

7.0661

2.0231

6.0590

7.1040

6.0036

7.0362

8.0143

8.0196

90407

9.0640 .,

7.1010

9.1322

9.0640

3.0469

3.0499

4.0386

4.0609

8.1057

9.0766

8.0870

6.0325

6.0691

Trimble, J. J.

Trimble, J. J.

Trofimov, V. S.

Trofimov, V. S.

Trott, B. D.

Trott, W, M.

Trott, W. M.

Trott, W. M.

Txzcinski, W.

Tsai, D. H.

Tulis, A. J.

Tulis, A. J.

Tulis, A. J.

Tulis, A. J.

LJdy, L. L.

Urizar, M. J.

Ursenbach, W. O.

Ursenbach, W. O.

Ursenbach, W. O.

Urtiew, P. A.

Urtiew, P. A.

Urtiew, P. A.

Utkin, A. V.

Vacellier, J.

Vacellier, J.

Valentini, J. J.

van der Steen, A. C.




van Thiel, M.

van Thiel, M.

van Thiel, M.

Van Dolah, R. W.

Van Dolah, R. W.

Van Dolah, R. W.

Vanpoperynghe, J.

Vanpoperynghe, J.

Vantine, H. C.

Vantine, H. C.

Vantine, H. C.

Velick.y, R. W.

Velicky, R. W.

Veliclcy, R. W.

Vermble, D.

Venable, D.

7.0247

7.0986

7.0789

9.0250

5.0191

8.0691

9.0153

9.1118

9.0766

8.0870

5.0047

6.0173

6.0183

9.0972

3.0150

3.0327

2.0519

2.0733

3.0357

5.0105

5.0119

9.0112

9.0050

5.0567

9.0842

8.0701

8.0710

9.0083

9.0320

9.0560

8.050 I

9.0425

9.0743

3.0436

4.0117

5.0081

8.0135

8.0892

7.0325

7.0466

7.1062

7.0898

7.0924

8.tJ251

4.0639

5.0003

.

.

. I

-1

*Iw

Name Sy.Page

Venable, D.

Venturini, E. L.

Verbeek, H. J.

Verbeek, H. J.

Verbeek, H. J.

Verdes, G.

Verdes, G.

Verdes, G.

Verhoek, F. H.

Vidart, A.

Vigil, M. G.

Vigil, M. G.

Voight, H. W.

Volk, F.

Volk, F.

Von Hone, W. G.

Von Hone, W. G.

Von Hone, W, G.

Von Hone, W. G.

Von Hone, W. G..

Von Rosen, K.

Voreck, W. E.● Voreck, W. E.

Voreck, W. E.

Vorthman, J.

Wachtell, S.

Wackerle, J.

Wackerle, J.

Wackerle, J.

Wackerle, J.

Wackerle, J.

Wackerle, J.

Wackerle, J.

Wagner, J.

Walker, E. H.

Walker, F. E.

Walker, G. R.

Walker, W. A.

Walker, W. A.

Wallace, A. A.

Walsh, E. K,

Walton, J.

Walton, J.

Walton, J.

Walton, J.

Wang Aiqin.m

5.0013

8.0485

8.0669

9.0083

9.0320

4.0039

5.0031

5.0041

3.0050

4.0527

8.1091

9.1385

8.0251

8.0577

9.0962

6.0691

7.0993

8.0003

8.1045

9.0133

9.1364

7.0924

8.0251

8.0460

8.0099

3.0635

4.0154

6.0020

7.0385

8.0099

8.0i23

9.0657

9.0683

8.0577

8.1119

7.0777

1.0039

4.0027

5.0597

6.0625

7.0394

6.0214

6.0729

7.0887

8.0613

8.1011


Name Sy.Page

Wang Tinzheng

Ward, S. H.

Wames, R.

Warren, T. W.

Wasley, R. J.

Wasserman, H. J.

Watson, J. L.

Watson, R. W.

Watson, R. W.

Watson, R. W,

Watson, R. W.

Watson, R. W.

Webber, P. E.

Wecken, F.

Wedaa, H. W.

Weingart, R. C.

Weingart, R. C.

Weingart, R. C.

Weingart, R. C.

Weingart, R. C.

Weingart, R. C.

Weingart, R. C.

Weinmaster, R. R.

Weirick, L. J.

Wenograd, J.

Wenograd, J.

West, C. E.

West, G. T.

Westmoreland, C.

Westmoreland, C.

Weston, A. M.

Weston, A. M.

Weston, A. M.

Weston, A. M.

Whatmore, C. E.

Whatmore, C. E.

Whitbread, E. G.

Whitbread, E. G.

Whitbread, E. G.

Whitbread, E. G.

Whitbread, E. G.

Wiedernmnn, A. H,

Wilkes, J. S.

Wilkins, M. L.

Wilkins, M. L.

Wilkins, M. L.

9.0816

8.0380

9.1131

9.0822

4.0239

8.0839

7.1048

4.0117

5.0081

5.0169

5.0559

6.0115

8.0294

4.0107

2.0251

6.0653

6.0755

7.0325

7.0425

7.1062

8.0003

8.1045

9.0822

9.1060

3.0010

3.0060

5.0533

7.0865

7.0256

7.0517

7.0256

7.0887

8.0914

9.028,0

7.0017

8.1035

2.0643

2.0695

3.0202

3.0574

3.0659

6.0336

7.0075

3.0721

4.0003

4.0519

Name Sy.Page

Williams, R. F.

Wilmot, G. B.

Winning, C. H.

Winslow, O. G.

Wiseman, L. A.

Witkowski, W.

Wittig, C.

Wlodarczyk, E.

Wolfe, A.

Wollenweber, U.

Wood, W. W.

Wood, W. W.

Woody, D. L.

Wrem, E.

Wright, P. W.

Wright> P. W.

Wu Xiong

Wu Xiong

Xiao Lianjie

Xu Laibin

Yakushev, V. V.

Yakushev, V. V.

Yang, L. C.

Yoneda, K.

Yoshida, M.

Yoshida, M.

Yu, J. M.

Yu Jun

Zaker, T. A.

Zerilli, F. J.

Zemow, L.

Zhang Guan-Ren

Zhang Guanren

Zhao Feng

Zhao Hengyang

Zimmerscheid, A. B.

Zirnmerscheid, A. B.

Zinrnan, W. G.

Zoe, J.

Zoe, J.

Zbellner, H.

Zoludeva, T. A.

Zou Quanqing

Zovko, C. T.

Zum, D. E.

Zwierzchowski. N. G

5.0427

9.0626

3.0455

6.0664

2.0643

9.0766

9.1084

9.0766

9.0918

8.1131

2.0312

2.0424

9.1243

6.0214

4.0142

4.0573

8.0796

9.0435

9.0435

8.1011

5.0399

6.0143

6.0612

8.0168

8.0993

9.0621

7.0343

9.1360

5.0313

9.0461

5.0067

7.0746

9.1360

9.0142

8.0083

6.0389

6.0740

2.0198

7.0602

8.0151

90066

9.0724

8.1011

3.0606

7.0216

9.1295

105


Name Sy.Page Name Sy.Page Name Sy.Page

.

.

Zwisler, W. H. 6.0162

.

.

‘,

.106

D. Acronym and Code Name IndexAlphabetic, First Reference

Name sy.Pg Makeup

1-MNT

1,1-DP

1,2-DB

1,2-DP

1,3-DP

2-IvfNT

2-NE

2,2-DB

2,2-DP

A-589

A-590

A-59 1

A-592

A-3

A-5

AAB 3189

. -3225

AAB 3267

a ABH

ADDF

ADNBF

ADNT

AF 902

AFX-521

AFX-108 E

AFX1 100

Amatex 20

Amatol

AMMoANANFO

ANFOAL- 10

AP

ATEC

B 2141

B ~142

B ~161

B 2169

B 2174

B ~190

B 2191.-

6.0232

5.0090

5.0237

5.0237

5.0090

6.0232

70762

5.0237

5.0237

5.0139

5.0139

5.0139

5.0139

9.0106

7.0551

7.089?

7.0892

7.0892

8.0528

6.0467

9.0566”

7.0801

9.0487

8.1106

9.1236

9.1284

6.0647

5.0501

9.0232

6.0439

3.0186

6.0546

5.0139

9.0539

7.0409

7.0409

8.0437

8.0437

8.0437

8.043~

8.0437

l-methyl-5 -nitrotetrazole

1,1-bis(difluoroamino) propane

l,2-bis(difluoramino) butane

1,2-bis(difluoramino) propane

l,3-bis(difluoramino)propane

2-methyl-5 -nitrotetrazole

2-nitroethanol

2,2-bis(difluora mino)butane

2,2-bis(difluoramino) propane

86 HMX/14 PB

80.3 HMX15.9 AP113.8 PB

69 HMX/17 AP/14 PB

57 HMX/29 AP/14 PB

91 RDX/9 wax

97 RDX13 wax

9.2 RDX160.8 AP/15 Al/l 5 binder

7,1 RDX/62.9 APf15 A1/15 binder

5 RDX/65 APi 15 Al/l 5 binder

C,4HbN,40,4

i ,4,4,10, 10,13 -hexafluoro-l, i ,7,7, 13, i 3-hexanitro-3,5,9, 11-tetraoxotm.hxane

7 amino-4,6 dinitrobenzofuroxan

ammonium salt of 3 ,5-dinitro-l ,2,4 -triazole

95 NQ/5 Viton A

95 PYX/5 Kel-F 800

82 RDX/18 O

66 TNT/16 OD2 wax/18 Al

20 RDX140 TNT140 AN

~()-6()% AN/8 f).40Y0 TNT

azidomethyl methyloxetane

ammonium nitrate

94.6 AN/5.4 fuel oil

87.4 AIW2.6 fuel oil/10 aluminum

ammonium perchlorate

acetyl triethyl citrate

88 RDX/12 HTPB

77 PETN/23 PU

40 HMX/30 AP/20 Al/l O polyurethane binder

83 PETN/ 17 polyurethane

47 HMX/30 AP/1 1 lead nitrate/12 polyurethane

30 PETN/70 HTPB

37 HMX/40 AP/1 1 lead ni[rate/12 polyurethane

I(J7

D. Acronym and Code Name Index (Continued)

Name sy.Pg Makeup

B ~192

B ~214

B 3003

Bnratol

Baratol

Baratol

Baratol 76

Baratol UK

BDNPA

BDNPA-F

BDNPF

BH-1

blasting gelatin

BO-I

BTF

BTFMA

BTNEN

BTX

BTZ

b Wx

BX1BX~

BX3

BX4

C-4

CAB

CACTP

Ccdosol 10

CEF

CH6

CMBD

Comp A

Comp A

Comp A-5

Comp A-5

Comp A 5

Comp A3

Comp B

Comp B

Comp B

Comp B

Comp B

Comp B

108

8.0437

9.1008

8.0437

3.0563

4.0361

6.0629

6.0647

9.0793

9.1018

9,1236

9.1018

8.0083

3.0045

8.0093

6.0712

6.0467

3.0070

6.0460

8.1019

2.0661

8.1106

8.1106

8.1106

8.1106

4.0097

9.0539

6.0455

9.1082

4.0005

9.0100

9.0007

3.0687

6.0647

7.0551

7.0928

8.0265

9.1463

2.0479

4.0048

6.0493

6.0629

6.0647

7,0353

27 HMX/50 AP/ 11 lead nitrate/12 polyurethane

12 HMX/72 NTO/16 inert binder

80 HMX/20 NC-NG1

76 barium nitrate/24 TNT




70 TNT/30 BaNO1

bis (2,2 -dinitropropyl) -acetal

eutectic

bis (2,2 -dinitropropyl) -formal

plastic-bonded RDX

91 NG/8 NC/1 chalk

plastic-bonded HMX, similar to PBX 9404

benzotrifuroxane

1-fluoro - 1,1-dinitro-4,4-bis(trifluoromethyl)-3 ,5-dioxohexane

bis-(2,2,2-trinitroethy l)nitramine

5,7-dinitro - 1-picrylbenzotriazole

bitetrazole

beeswax

60 TATB/35 (95 RDX/5 HMX)/5 Kel-F

60 TATB/35 (95 RDX/5 HMX)/5 PTFE

60 TATB/35 (90 RDX/10 HMX)/5 Kel-F

60 TATB/35 (90 RDX/10 HMX)/5 PTFE

9 I RDX/9 wax

cellulose acetate butyrate

catena-p-cyanotetraammine cobalt(III) perchlorate

B ,&lz (CsN03 )2

tris 13-chloroethylphosphate

97.5 RDX/O.5 polyisobutylene/O.5 calcium stearate/O.5 graphite

NCfNG/HMX/Al/AP

91 RDX/9 wax ‘,92 RDX/8 wax

97 RDX/3 wax

98 RDX/2 stemic acid

98.5 RDX/1.5 stearic acid

91 RDX/9 polyethylene

60 RDX/40 TNT, wax and other additives [ 1 to 1.5%)

60 RDX/40 TNT

60 RDX/40 TNT/1 wax

59.5 RDX/39.5 TNTII beeswax

63 RDX/36 TNT/1 wax

45 RDX/55 TNT/1 wax

.

.

.

.


Name sy.Pg Makeup

Comp B (ISL)

Comp B-3

Comp B-3

Comp B-3

Comp B-3 (ISL)

Comp B, Grade A

Comp B, Grade A

Comp B3 (waxed)

Comp B4

CP

CTX-1

CW3CX-84CX-84ACyclonite

Cyclotol

Cyclotol

Cyclotol 25/75

Cyclotol 60/40.Cyclotol 77/23.D-z

LDATB

DDNP

Debrix 18AS

Debrix-2

DEGDN

DFB

DFF

DFNT

DHE

DINA

DINGU

DiTeU

Dithekite

Dithekite 13

Dithekite 13/20

DNNC

DNP

DNPA

DNPF

DNPP

DNPTB

7.0317

4.0361

5.0004

9.1236

70317

4,0005

5.0198

5.0280

7.0900

6.0455

8.0265

9.1323

8.0366

9.1482

3.0437

3.0502

5.0065

9.1236

9.1236

6,0647

9.1236

3.0761

3.0012

8.0265

8.1106

7.0762

6.0467

6.0467

6.0467

8.0365

3.0066

7.0540

4.0435

3.0186

3.0493

2.0648

9.0232

7.0374

4.0005

3.0685

6.0467

3.0070

65 RDX/35 TNT

64 RDX/36 TNT

60~ 1.5 RDX/40*1.5 TNT

60 RDX/40 TNT -

60 RDX/40 TNT

64 RDX/36 TNT

59.5 RDX139.5 TNTJ1.O wax

60 RDX/40 TNT/l wax

60 RDX/40 TNT, no wax

1-(j-cyanotetrazolato) pentaammine cobalt(HI) perchlomte

15 RDX/40 AP/23 A1122 TNT + additives

analog of 60 RDX/40 TNT

84 RDX/9.7 R45-HT/5.6 DOA/O.7 TDI

84 RDX/16 HTPB

RDx65 RDX/35 TNT

72 RDX/25 TNT

25 RDX/75 TNT

60 RDX/40 TNT

77 RDX/23 TNT

84 D2 wax/14 NC/2 lecithin

1,3-diamino-2,4,6 -trinitrobenzene

diazodinitrophenol

95.5 RDX/2.5 wax12 additives

95 RDX/5 wax

diethylene glycol dinitrate

2,2-difluoro-2-nitroethly-5,5-difluoro-2-(3',3'-difluoro-3'-nitro- 1-oxopropyl)-

5,5-dinitro-3-oxopentanoate

bis(2-fluoro-2,2 -dinitroethyl)difluoroformal

2,2difluoro-2-nitroethy l-trifluoromethane -sulfonate

2-hydroxymethyl dimethylhydantoin

di-13-nitroxyethyl nitramine .,

dinitroglycolurile

dinitroethyl-uric (sic)

a mixture of 82.8°/0 nitric acid, nitrobenzene, and water

63 nitric acirU24 nitrobenzene/13 water

dithekite with 13/20 wt’Yowater

1,3,5,5 -tetrrmitro-hexahy dropyrimidine

dinitrophenol

2,2-dinitropropy lacrylate

bis-dinitropropyl fumarate

2,2-dini[ropropyl perchlomte

2,2-dinitropropy1 4,4,4 -trinitrobutyrate

:

D. Acronym and Code Name index (Continued)

Name sy.Pg Makeup

DNT

DNT

DOA

DOP

DREV-Explosive

EA

EAK

EAR

EARK

EARL-1

EARL-2

EDC-29

EDC-32

EDC-35

EDD

EDNA

EDNP

EE

EGD

EGDN

EGN

EIE

EJC-90

Emulite

EN

Estane

ET

EtDP

eutectlc

FDA

FDE

FDEE

FDEK

FDNE-A

FDNE-N

FDNE-S

FDNEP

FEFO

FNR

FO

FT-1

110

7.0374

7.0802

8.0363

4.0005

8.0363

7.0548

8.1002

7.0551

7.0551

7.0551

7.0551

9.0793

9.0793

9.0123

6.0439

6.0314

5.0139

9.0585

3.0456

3.0438

2.0659

4.0159

9.1236

8.1071

3.0813

4.0005

3.0744

4.0005

9.1015

6.0467

6.0467

6.0467

7.0804

6.0467

6.0467

6.0467

6.0467

6.0467

4.0005

6.0546

9.0879

dinitrotoluene

3,5-dinitro- 1,2,4 -triazole

dioctyl adipate

dioctylphthalate

84 RDX/ 16 polybutadiene

50 EDD(ethylenediamine dinitrate)/50 AN

46 ethylenediamine dinitrate/46 ammonium nitrate/8 potassium nitrate

42.5 EDD/42.5 AN/15 RDX

42.5 EDD/36. 1 AN/15 RDX/6.4 potassium nitrate

40.3 EDD/40.3 AN/14.2 RDX/5.2 Al

36.2 EDD/36.2 AN/12.8 RDX/14.8 Al

95 HMX/5 polyurethane

85 HMX/15 Viton

95 TATB/5 Kel-F 800

ethylenediamine dinitrate

ethylenedinitramine

ethyl -4,4 -dinitropentanoate w/1 0/0Cab-O-Sil gelling agent

emulsion explosive

ethylene glycol dinitrate



exchanged-ion explosive (10 NG/90 stoichiometric ammonium chlorlde-

potassium nitrate mixture)

26 HMX/ 14 NC/32 NG/5 AP/18 A1/5 O

AN/FO/water with gas-filled microsphere

ethyl nitrate

trademark for polyester-urethane of adipic acid 1,4-butanediol,

diphenylmethane diisocyanate

homogeneous mixture of ethyldecabomne in tetranitromethane

ethyl 4,4-dinitropentanoate

50 BDNPA/50 BDNPF

bis(2-fluoro-2,2 -dinitroethyl) acetal .,

1,1,4-trifluoro- 1,4,4 -trinitro-3 -oxobutane

1,5,-difluoro - 1,1 ,5,5 -tetranitro-3-oxopentane

2.55 AN/O.3 ADNT/1 EDD/O.36 potassium nitrate, the numbers are vol%

1,9-difluoro- 1,1,5,5,9,9 -hexanitro-3 ,7-dioxononane

2-fluoro-2,2,-dinitroethyl nitrate

bis[2-tluoro-2,2 -dinltroethyl)sul fate

2-fluoro-2,2-dinitroethyl perchlorate

bis(2-tluoro-2,2 -dinitroethyl)formal

tetrafluoroethy lene-Lrifluoro-nitroso methane copolymer

fuel oil #1

21 thiokol/8 A1/65AP

.

.

,


Name sy.Pg Makeup

FT-2

FTE

GBFO

GMB

Gurit

H-6

HA-IN

H19

HAV-10

HAV-20

HBX

HBX

HBX- 1

HBX- 1

HBX-3

HCX

HDBA

heat powder

. HEP

Hexatol 60/40

Hexatonal 15.t

Hexogen

Hexotol 60/40

Hexotolif 15

Hexotonal 15

HH

HMTA

HMX

HN

HNAB

HNB

HNDZ

H-Ns

HTPB

HV4

HW4

HX72

HX78

HXA123

IBA

ICCP

IPDI

JA2

90879

6,0467

6.0467

8.0993

8.1071

5.0255

9.0487

9.1061

5.0139

5.0139

2.0737

5.0073

5.0524

9.1236

9.1236

8.1011

8.C1365

9,1082

8.0883

6.0546

6.0546

4.0159

6.0511

6.0511

6.0511

9.0940

4.0184

6.0”712

10027

7.0416

7.0647

9.0232

5.0222

8.1036

5.0280

5,0280

9.0963

9.0963

9.0963

5.0237

6.0455

8.1036

9.0539

11 HTPB/18 A1/68 AP

1,1, 1,4-tetrafluoro-4,4 -dinitro-3-oxobutane

l;12-difiuoro-l,1 ,12,12 -tetranitro- 3,5,8,10 -tetraoxododecane

glass microballoons

NG/EGDN/SiOz

45 RDX/30 TNT120 A1/5 wax

21 hydrazine/79 hydrazine nitrate

32 A1/5 AP/51 KC1/9 HTPB/2 DOA

74.7 HMX/10.6 A1/14.7 Viton

65.7 HMX/18.9 A1/15.4 Viton

45 RDX130 TNT125 Al

75 Composition B/25 Al

40 RDX/38. 1 TNT/17. 1 A1/4.8 Wax

40 RDX/36 TNT/19 A1/5 D-2

30 RDX126 TNT138 A1/6 D-2

heterogeneous composite explosive

4-hydroxy-N-N-dimethy lbutyramlde

88 Fe/l 2 KP

high-energy propellant

59 RDX140 TNT/1 wax

42.1 RDX142.1 TNTIO.8 wax/15 Al

RDx

60 RDX140 TNT

42.5 RDX/42.5 TNT/15 LiF

42.5 RDX/42.5 TNT/15 Al

hydrazine hydrate

hexamethylenetetramine

cyclotetmrnethy lene tetranitramine

h~drazine mononitrate

hexanitroazobenzene

hexanitrobenzene

i,3,3 ,5,7,7 -hexanitrodiazacy clooetpne

hexanitrostilbene

hydroxyl-terminated polybutadiene

85 HMX115 Viton

95 HMX15 wax

80 RDX/20 PB

55 NQ/30 RDX/15 PB

70 RDX/15 PB/15 Al

1,2-bis(difluoramino) -2-methylpropane (isobutylene adduct)

isothiocyanatopentaammine cobalt(III) perchlora[e

isophorone diisocyanate

59 NC/15 NG/25 DEGDN

?Ill


Name sy.Pg Makeup

KHNO

KP

LAC

LP

LS

LX-03-0

LX-04-1

LX-07

LX-07-O

LX-09

LX-10

LX-1 1

LX-13

LX-14

LX-15

LX-17

M-FEFO

M~

M5

h

MAN

MDF

MEDINA

MF

MF

MFDNB

MFF

Minol 2

MMAN

MN

NB-40

NC

NF

NG

NG1

Nigu

Nitromixturc

NM

NME

NONA

NQ

NTO

o

[]~

9.1082

5.0139

9,0975

5.0139

8.0711

91~36

4.0489

5.0065

4,0005

5.0065

5.0065

5.0139

8.109 I

8.0614

8.1106

7.0488

6.0467

9,0539

9.0539

6.0467

6.0439

9.1510

3.0674

6.0467

8.0711

6.0467

6.0467

4.0463

7.0374

5.0267

6.0771

4.0005

9.0995

3.0066

7.0043

8.0577

2.0648

4.0126

9.1019

5.0222

7.0566

9.1001

9.1236

potassium salt of hexanitro diphenylamine

potassium perchlorate

~-lactose

lithium perchlorate

lead styphnate, Pb(CbOw3H,)

70 HMX/20 DATB/10 Viton A

85 HMX/15 Viton, “ 1” denotes fine-particle-sized HMX

90 HMX/10 Viton

90 HMXI1O Viton

93.3 HMX14.2 DNPAJ2.5 FEFO

95 HMX/5 Viton

80 HMX/20 Viton

80 PETN/20 Sylgard (see XTX-8003)

95.5 HMX/4.5 Estane 5702-F I

95 HNS/5 Kel-F 800

92.5 TATB/7.5 Kel-F (formerly RX-03-BB)

1,7-difluoro-4-(1 -oxomethyl)- 1,1,7,7-tetranitro- 3,5-dioxoheptane

75 NC

82 NC/20 NG

1, 1,7-trifluoro-4 -methyl-l ,7,7 -trinitro-3,5-dioxoheptane

methylammonium nitrate

mild detonating fuse or fuze

CHdNd04, methylene dinitramine

1,1,7-trifluoro- 1,7,7 -trinitro-3 ,5-dioxoheptane

mercury fulminate, Hg(ONC)z

methyl-4 -fluoro-4,4-dinitrobuty rate

1,4,4,7,7-pentafluoro- 1,1,7-trinitro-3 ,5-dioxoheptane

aluminized ammonium nitrate/TNT

monomethylamine nitrate

methylnitrate

60 pyroxyline/40 nitroglycerine

nitrocellulose

nitroform

nitroglycerin

nitroglycol

nitroguanidine

83% nitromethane/17 2-nitropropane

nitromethane

nitromethane

nonanitroterphenyl

nitroguanidine

3-nitro- 1,2,4 triazole-5-one

other material

‘,

.

.

.

.

m

.


Name sy.Pg Makeup

‘9

Octogen

Octol

Octol

Octol

Octol-A

Octol-B

Octorane 86A

0RA86

OTTOp~]oo B

PA

PB

PB

PBX-0280

PBX-0280/PE

PBH-9D

PBX-9010

PBX-901O

PBX-90110

PBX-9011.PBX-9205

%PBX-9404

PBX-9404-03

PBX-9407

PBX-9501

PBX-9502

PBX-9503

PBXC-I 17

PBXC-121

PBXN-5

PBXN-103

PBXW

PBXW-7

PBXW-106 E

PBXW-108 I

PBXW-109 E

PBXW-109 I

PBXW-I 13 II

PBXW-114 II

PBXW-115

Pc

PE

PE 4

9.1236

4.0005

6.0647

9.0069

5.0280

5.0280

9.1047

9.1008

6.0467

80626

3.0700

5.0139

8 1132

9.1463

9.1463

9.0144

4.0005

9.1082

4.0005

9.1083

5.0599

5.0060

4.0005

7.0928

6.0647

7.0052

8.1106

9,1236

9.1236

7,0928

9.1236

8.0883

9.0106

9.1236

9.1236

9.1236

9.1236

9.1236

9.1236

9.0806

3.0323

6.0543

8.0265

HMX

78 HMX/22 TNT

77 HMX/23 TNT

64 RDX/36 TNT

80 HMX120 TNT/1 Wax

70 HMX/30 TNT/1 Wax

84 HMX/16 PU

86 HMX/14 inert binder

1,1,1 ,7,7,13,13,13 -octafluoro-4,4,10, 10-tetranitro- 2,6,8,1 2-tetraoxotridec~ne

88 HMX/12 HTPB

picric acid

hydroxyterminated polybutadiene

polybutadiene

95 RDX/5 Estane

95 RDX/5 polyethylene

HMX, plastic bonded

90 RDX/10 Kel-F

90 HMW1O Kel-F 800

90 HMX/1 O Estane

90 HMX/1 O Estane

92 RDX/6 polystyrene/2 dioctyl phthalate

94 HMX/3 nitrocellulose/3 tris-13-chloroethyl phosphate

94 HMX/3 NC/3 CEF

94 RDX/6 EXON 461

95 HMX12.5 Estane/l .25 BDNPAI1 .25 BDNPF

95 TATB/5 Kel-F 800 (formerly X-0290)

80 TATB/15 HMX/5 Kel-F 800

71 RDX/17 Al/l 2 other

82 HMX/18 other

95 HMX/5 Viton A

23 TT140 AP127 Al/l O other

RDX/inert binder

36 RDX160 TATB/5 Viton A

75 RDX/18 E3DNPA-F/7 other

85 RDX/15 other

64 RDX120 All 16 other

65 RDX120 Al/l 5 other

68 HMX/ 12 other

78 HMX/10 Al/l 2 other

20 RDX143 AP125 Al/l 2 HTPB

Primacord

86 PETN/14 wax

88 RDX/12 plasticizer.

.?


Name sy.Pg Makeup

PE 6

Pentanex

Pentolite

PETN

PHX3 1

Polystyr

PSF

PTFE

PVA

PYX

QMAN

RDx

RDx

REX-20

RGPA

RX-03-BB

RX-04-AT

RX-04-AU

RX-04-AV

RX-04-BM

RX-04-BN

RX-04-BO

RX-04-BT

RX-04-BY

RX-04-DS

RX-04-P 1

RX-OS-AA

RX-08-EL

RX-08-FL

RX-08-GB

RX-08-GG

RX-09-AA

RX-1 1-AF

RX- 11-AI

RX-1 1-AJ

RX-1 1-AW

RX-1 l-AX

RX-1 1-AY

RX-11-AZ

RX-1 I-BA

RX-

RX-

RX-

114

8-AB

8-AE

8-AG

5.0139

6.0546

1.0014

3.0012

9.0963

4.0005

9.0822

6.0626

2.0712

8.1106

6.0439

5.0222

7.09?8

6.0467

8.0265

7.0488

4.0005

5.0139

4.0005

5.0139

5.0139

5.0139

5.0139

4.0005

5.0139

4.0005

4.0005

9.1312

9.0007

9.0026

9.0026

4.0005

5.0139

5.0139

5.0139

5.0139

5.0139

5.0139

5.0139

5.0139

5.0139

5.0139

5.0139

6-polyethylene

45 PETN/37 AN/2 glycol/1 5.5 water/O.5 guar

50 PETN/50 TNT

pentaerythritol tetranitrate

85 RDX/15 Cariflex 1107

polystyrene

polysulfone

polytetrafluoroethy lene

polyvinyl alcohol

2,6-bis(picrylamino) -3,5 -dinitropyridine

tetramethylammonium nitrate

cyclotrimethylenetrinitramine

1,3,5-trinitro 1,3 ,S-tetrazacyclohexane

2,2,2 -trifluoroethyl-4 -fluoro-4,4-dinitrobuty rate

70 RDX/I 9 plasticizer/5.5 polyurethane/5.5 ?

92.5 TATB/7.5 Kel-F (new name is LX-17)

88 HMX/12 carborane-fluorocarbon copolymer

92 HMX/8 Viton

92 HMX/8 PE

81.6 HMX/4 A1/14.4 Viton

79 HMX/6.6 A1/14.3 Viton

72.7 HMX/13.3 A1/14.O Viton

76 HMX/1 O LiF/14 Viton

86 HMX/14 FNR

81 HMX19.9 A1/9. 1 Viton

80 HMX/20 Viton

80 RDX/8 polystyrene/2 DOP

73 HMX/25 FEFO/1 PCL 240/other

75.9 W22.2 FEFO/1.9 polyvinyl binder

61 HMX/36 FEFO/3. 1 urethane

61 HMX/36 FEFO/3. 1 urethane

93.7 HMX/5.7 DNPA/O.6 EtDP ‘,

52 HMX/43 KP/5 PE

52 HMX/43 KP/5 PE

52 HMX/43 KP15 PE

51 HMX/35 KP/14 PB

51 HMX/35 KP/14 PB

33.4 HIvDU53.4 KP/13.2 PB

33.4 HMX/53.4 KP/13.2 PB

51 HMX/39 AP/10 Viton

51 HMX/20 AP/29 EDNP



●

&

.


Name syoPg Makeup

RX-18-AH

RX-18-AJ

RX-18-BA

RX-22-AG

RX-23-AA

RX-23-AB

RX-23-AC

RX-25-AA

RX-25-BF

RX-25-BH

RX-25-BP

IUC-25-BQ

RX-26-AF

RX-30-AA

RX-30-AB

RX-30-AC

RX-30-AD

RX-30-AE

0 RX-30-AFo

RX-31-AA

RX-31-AB●

RX-35-AP

RX-36-AA

RX-36-AB

RX-36-AC

RX-36-AD

RX-36-AE

RX-36-AF

RX-36-AG

RXAC

s-TCB

S-2

SPIS-44

SRI- I

SRI-2

SRI-3

SRI-4

SRI-5

SX-2

SYEP

T

T1

T~

5.0139

5.0139

5.0139

5.0139

6.0712

6.0712

6.0712

5.0139

9.0526

9.0526

9.0526

9.0526

7.0059

6.0731

6.0731

6.0731

6,0731

6.0731

6.0731

6.0731

6.0731

9.1313

8.1020

8.1020

8.1020

8.1020

8.1020

8.1020

8.1020

8.0802

7.0425

9.1236

7.0620

6.0467

6.0467

6.0468

6.0468

6.0468

6.0493

6.0468

7.0697

8.0151

8.0151

71 HMX/29 EDNP

52.6 HMX/34.7 KP/12.7 PB

31 HMX/45 KP/24 EDNP

73.6 HMX126.4 LP

79 hydrazine nitrate/21 hydrazine

70 hydrazine nitrate/5.9 hydrazine124. 1 water

30 hydrazine nitrate170 hydrazine

22 HMX/58 API1O A1I1O Viton

38 HMX/36 AP122 ZrHz /4 Estane

19 HMX/47 AP130 ZrHz 14 Estane

38 HMX/36 AP122 ZrH2 /4 Estane

38 HMX136 AP122 ZrHz 14 Estane

49.3 HMX/46.6 TATB/4. 1 Estane

60.8 AP138 NM/l.2 guar

61.1 AP/37.9 NM/l guar

47.6 KP150.8 NM/l.6 guar

47.1 KP/51.3 NM/guar 1.6

57.9 AN/40.8 NM/1.3 guar

57.9 AN/40.8 NM/1.3 guar

28.8 AN147 NM122.8 Al/l .4 guar

43.2 AN/47 Nh4/8.3 A1/1.5 guar

60 HMX/40 NG, TA, PEG binder

1 HMX/1 TATB/1 BTF, note mole ratios

1 TATB/1 BTF, note mole ratios



1 HMX/1 BTF, note mole ratios

1 HMX/1 TATB, note mole ratios


70 hydrazinef 30 hydrazine nitrate

symmetrical 1,3,5-trichlorobenzene (precursor to TATB)

63 RDX/22 TNT/15 Al ‘,

20 HMX149 AP/21 Al/l O binder

1,1,1 -trifluoro-4,4,4 -trinitro-2-oxobutane

1,1, 1,4-tetrafluoro-4,4 -dinitro-2-oxobutane

1,1,1 -trifluoro-4,4-dinitro -2-oxopentane

1,1, 1,7,7,7 -hexafluoro-4,4 -dinitro-2,6-dioxoheptane

1-fluoro- 1,1,3 ,3-tetranitro-5 -oxohexane

RDX/filler, sheet explosive

4,4-bis(difluoramino)- 1,7-difluoro- 1, 1,7,7-tetranitro- 3,5-dioxoheptane

95.5 TATB/4.5 Viton

95.5 TATBI?

97 TATBt?

115


Name sy.Pg Makeup

TA

TATB

TBP

TCE

TCTNB

TDI

TDPF

Tet~l

TEA

TFMA

TFMDA

TFMFF

TFNA

TMETN

TNA

TNB

TNETB

TNT

INTAB

TO

Torpex

Torpex 2B

TPH12076

Tritonal

Tro[yl

TS3659

TT

TZL-4

TTF

UFD

UGS

UP

UPS

Viton

WAK2Wc 231

WC140

WC23 1

WG-2

WG-4

~.o~o~

X-0219

116

2.0659

6.0659

9.1236

7.0374

7>0425

8.0363

6.0468

6.0427

6.0468

6.0468

6.0468

6.0468

8.0802

3.0813

8.0746

? 0066

3.0070

4.0126

3.0066

8.0802

9.1001

4.0463

8.0265

9.1061

2.0735

9.1236

9.0297

9.1236

9.0232

6.0468

9.0407

9.1062

6.0450

6.0450

5.0139

9.1062

8.0883

9.0297

9.0297

6.0546

6.0546

4.0005

6.0647

triacetin

1,3 ,5-&iamino-2,4,6 -trinitrobenzene

tris-&chloroethyl phosphate

trichloroethylene

1,3 ,5-trichloro-2,4,6 -trinitrobenzene (precursor for TATB)

toluenediisocyanate

1,1,1, 13,13,13 -hexafluoro-4,4,10,10 -tetranitro- 2,6,8,12 -tetraoxotridecane

N-methyl-N-nitro-2,4,6 -trinitroaniline

1,7,difluoro- 1,1,7,7 -tetranitro-4-tri fluoromethyl- 3,5-dioxoheptane

1-fluoro- 1,1-dinitro-4-trifluoromethyl-3 ,5-dioxohexane

1-fluoro-4-difluoronitromethyl-l, 1-dinitro-4-trifluoromethyl-3, 5-dioxoheptane

1,1, 1,4,4,7 -hexafluoro-7,7 -dinitro-3 ,5-dioxoheptane

1,1,1 -trifluoro-3 ,5,5 -trinitro-3-azahexane

trimethylolethane trinitrate

trinitroaniline, picramide

1,3,5 trinitrobenzene

2,2,2 -trinitroethyl-4,4,4 -trinitrobu~rate

tetranitromethrme

2,4,6 -trinitrotoluene

1,3 ,5-triazido-2,4,6 -trinitrobenzene

1,2,4 -triazole-5-one

aluminized RDX/TNT

42 RDX/40 TNT/18 A1/5 desensitizer

A1/AP/HTPB

80 TNT120 Al

TNT

79.9 NC/2 1.6 NG

trimethylolethane trinitrate

l,5-dinitro-tetrazole

1,1,1 -trifluoro-7,7,7 -trinitro-3 ,5-dioxoheptane

ultraflne diamonds

20 DBP/5 A1/65 NazSO, /9 HDAP ‘,

ureamonoperchlorate

90 wt~. aqueous solution of UP

vinylidine fluoride-hexafluoropropy lene copolymer

A1/HMX/AP

75 NC/25 NG “commercial

98 NC

74.8 NC/25.2 NG

MMAN-sensitized watergel

MMAN-sensitized watergel

83 HMX/17 Teflon

90 TATB/1 O Kel-F 800

reloading powder”

explosive 70/0 Al

explosive 130/o Al


Name Sy.?g Makeup

X-0233

X-0242

X-0290

X-0319

X-0320

X-032 1

X-0341

X-0342

X-0343

X-0344

X-0407

X-0420

X-0430

X-0432

X-0444

xl

XM39

XTX-8003

* Z TACOT

Zox:Zox

*ZPCP

8.0979

9.1015

6.0637

7.0567

7.0567

7.0567

7.0567

7.0567

7.0567

7.0567

8.0123

9.0487

9.1015

9.0487

9.1015

8.0151

9.0539

6.0647

8.0528

9.0995

9.0995

9.1083

85.48 tungstenfl 3.22 HM.X/O.8 polystyene/O.5 DOP

94 HMX/3 Estane15 eutectic

95 TATB/5 Kei-F 800 (changed to PBX 9502)




90.25 TATB/4.75 HMX/5 Kel-F 800

85.5 TATB/9.5 HMX/5 Kel-F 800

80.75 TATB/14.25 HMX/5 Kel-F 800

71.25 TATB/23.75 HMX/5 Kel-F 800

70 TATB/25 PETN/5 Kel-F

94 DINGLV5 Exon/1 titanate

88 HMX/6 Kratoti6 Tufflo oil

57 DINGLV43 TNT

88 HMX16 Estane/6 eutectic

96 I-IMXI?

76 RDX/15 NG/12 CAB/8 ATEC

80 PETIW20 silicone rubber

C,,H4N80B

zero-oxygen-balance explosive

2,2,2 -trinitro ethyl-N-nitroethy lenediamine

azidopentamine cobalt (III) perchlorate

‘t

a

:

4

117

Documents

Indexes for the Proceedings