HANDBOOK OF POLYMER SYNTHESISDK1229_half-series-title.qxd
11/24/04 2:21 PM Page ACopyright 2005 by Marcel Dekker. All Rights
Reserved.PLASTICS ENGINEERINGFounding EditorDonald E.
HudginProfessorClemson UniversityClemson, South Carolina1. Plastics
Waste: Recovery of Economic Value, Jacob Leidner2. Polyester
Molding Compounds, Robert Burns3. Carbon Black-Polymer Composites:
The Physics of Electrically ConductingComposites, edited by Enid
Keil Sichel4. The Strength and Stiffness of Polymers, edited by
Anagnostis E. Zachariadesand Roger S. Porter5. Selecting
Thermoplastics for Engineering Applications,Charles P. MacDermott6.
Engineering with Rigid PVC: Processability and Applications, edited
by I. Luis Gomez7. Computer-Aided Design of Polymers and
Composites, D. H. Kaelble8. Engineering Thermoplastics: Properties
and Applications, edited by James M. Margolis9. Structural Foam: A
Purchasing and Design Guide, Bruce C. Wendle10. Plastics in
Architecture: A Guide to Acrylic and Polycarbonate,Ralph
Montella11. Metal-Filled Polymers: Properties and Applications,
edited by Swapan K. Bhattacharya12. Plastics Technology Handbook,
Manas Chanda and Salil K. Roy13. Reaction Injection Molding
Machinery and Processes, F. Melvin Sweeney14. Practical
Thermoforming: Principles and Applications, John Florian15.
Injection and Compression Molding Fundamentals, edited by Avraam I.
Isayev16. Polymer Mixing and Extrusion Technology, Nicholas P.
Cheremisinoff17. High Modulus Polymers: Approaches to Design and
Development,edited by Anagnostis E. Zachariades and Roger S.
Porter18. Corrosion-Resistant Plastic Composites in Chemical Plant
Design,John H. Mallinson19. Handbook of Elastomers: New
Developments and Technology, edited by Anil K. Bhowmick and Howard
L. Stephens20. Rubber Compounding: Principles, Materials, and
Techniques, Fred W. Barlow21. Thermoplastic Polymer Additives:
Theory and Practice, edited by John T. Lutz, Jr.22. Emulsion
Polymer Technology, Robert D. Athey, Jr.23. Mixing in Polymer
Processing, edited by Chris Rauwendaal24. Handbook of Polymer
Synthesis, Parts A and B, edited by Hans R. Kricheldorf25.
Computational Modeling of Polymers, edited by Jozef Bicerano26.
Plastics Technology Handbook: Second Edition, Revised and
Expanded,Manas Chanda and Salil K. RoyDK1229_half-series-title.qxd
11/24/04 2:21 PM Page BCopyright 2005 by Marcel Dekker. All Rights
Reserved.27. Prediction of Polymer Properties, Jozef Bicerano28.
Ferroelectric Polymers: Chemistry, Physics, and Applications,
edited by Hari Singh Nalwa29. Degradable Polymers, Recycling, and
Plastics Waste Management, edited by Ann-Christine Albertsson and
Samuel J. Huang30. Polymer Toughening, edited by Charles B.
Arends31. Handbook of Applied Polymer Processing Technology, edited
by Nicholas P. Cheremisinoff and Paul N. Cheremisinoff32. Diffusion
in Polymers, edited by P. Neogi33. Polymer Devolatilization, edited
by Ramon J. Albalak34. Anionic Polymerization: Principles and
Practical Applications, Henry L. Hsiehand Roderic P. Quirk35.
Cationic Polymerizations: Mechanisms, Synthesis, and Applications,
edited by Krzysztof Matyjaszewski36. Polyimides: Fundamentals and
Applications, edited by Malay K. Ghosh and K. L. Mittal37.
Thermoplastic Melt Rheology and Processing, A. V. Shenoy and D. R.
Saini38. Prediction of Polymer Properties: Second Edition, Revised
and Expanded,Jozef Bicerano39. Practical Thermoforming: Principles
and Applications, Second Edition,Revised and Expanded, John
Florian40. Macromolecular Design of Polymeric Materials, edited by
Koichi Hatada,Tatsuki Kitayama, and Otto Vogl41. Handbook of
Thermoplastics, edited by Olagoke Olabisi42. Selecting
Thermoplastics for Engineering Applications: Second Edition,Revised
and Expanded, Charles P. MacDermott and Aroon V. Shenoy43.
Metallized Plastics, edited by K. L. Mittal44. Oligomer Technology
and Applications, Constantin V. Uglea45. Electrical and Optical
Polymer Systems: Fundamentals, Methods, and Applications, edited by
Donald L. Wise, Gary E. Wnek, Debra J. Trantolo,Thomas M. Cooper,
and Joseph D. Gresser46. Structure and Properties of Multiphase
Polymeric Materials, edited by Takeo Araki, Qui Tran-Cong, and
Mitsuhiro Shibayama47. Plastics Technology Handbook: Third Edition,
Revised and Expanded, Manas Chanda and Salil K. Roy48. Handbook of
Radical Vinyl Polymerization, edited by Munmaya K. Mishra and Yusef
Yagci49. Photonic Polymer Systems: Fundamentals, Methods, and
Applications, edited by Donald L. Wise, Gary E. Wnek, Debra J.
Trantolo, Thomas M. Cooper, and Joseph D. Gresser50. Handbook of
Polymer Testing: Physical Methods, edited by Roger Brown51.
Handbook of Polypropylene and Polypropylene Composites, edited
byHarutun G. Karian52. Polymer Blends and Alloys, edited by Gabriel
O. Shonaike and George P. Simon53. Star and Hyperbranched Polymers,
edited by Munmaya K. Mishra and Shiro Kobayashi54. Practical
Extrusion Blow Molding, edited by Samuel L. Belcher55. Polymer
Viscoelasticity: Stress and Strain in Practice, Evaristo
Riande,Ricardo Daz-Calleja, Margarita G. Prolongo, Rosa M.
Masegosa, and Catalina Salom56. Handbook of Polycarbonate Science
and Technology, edited by Donald G. LeGrand and John T.
BendlerDK1229_half-series-title.qxd 11/24/04 2:21 PM Page
CCopyright 2005 by Marcel Dekker. All Rights Reserved.57. Handbook
of Polyethylene: Structures, Properties, and Applications, Andrew
J. Peacock58. Polymer and Composite Rheology: Second Edition,
Revised and Expanded,Rakesh K. Gupta59. Handbook of Polyolefins:
Second Edition, Revised and Expanded, edited by Cornelia Vasile60.
Polymer Modification: Principles, Techniques, and Applications,
edited by John J. Meister61. Handbook of Elastomers: Second
Edition, Revised and Expanded,edited by Anil K. Bhowmick and Howard
L. Stephens62. Polymer Modifiers and Additives, edited by John T.
Lutz, Jr., and Richard F. Grossman63. Practical Injection Molding,
Bernie A. Olmsted and Martin E. Davis64. Thermosetting Polymers,
Jean-Pierre Pascault, Henry Sautereau, Jacques Verdu, and Roberto
J. J. Williams65. Prediction of Polymer Properties: Third Edition,
Revised and Expanded, Jozef Bicerano66. Fundamentals of Polymer
Engineering, Anil Kumar and Rakesh K. Gupta67. Handbook of
Polypropylene and Polymer, Harutun Karian68. Handbook of Plastic
Analysis, Hubert Lobo and Jose Bonilla69. Computer-Aided Injection
Mold Design and Manufacture, J. Y. H. Fuh, Y. F. Zhang, A. Y. C.
Nee, and M. W. Fu70. Handbook of Polymer Synthesis, Second Edition
Hans R. Kricheldorf, GrahamSwift, and Oskar
NuykenDK1229_half-series-title.qxd 11/24/04 2:21 PM Page DCopyright
2005 by Marcel Dekker. All Rights Reserved.Marcel Dekker New
YorkHans R. Kr i c hel dor fUniversitt HamburgHamburg, GermanyOs k
ar NuykenTechnical UniversityMnchen, GermanyGr aham Sw i f tGS
Polymer ConsultantsChapel Hill, North Carolina, U.S.A.HANDBOOK
OFPOLYMER SYNTHESISSec ond Edi t i onDK1229_half-series-title.qxd
11/24/04 2:21 PM Page iCopyright 2005 by Marcel Dekker. All Rights
Reserved.Although great care has been taken to provide accurate and
current information, neither theauthor(s) nor the publisher, nor
anyone else associated with this publication, shall be liable
forany loss, damage, or liability directly or indirectly caused or
alleged to be caused by this book. Thematerial contained herein is
not intended to provide specic advice or recommendations for
anyspecic situation.Trademark notice: Product or corporate names
may be trademarks or registered trademarks andare used only for
identication and explanation without intent to infringe.Library of
Congress Cataloging-in-Publication DataA catalog record for this
book is available from the Library of Congress.ISBN:
0-8247-5473-5This book is printed on acid-free
paper.HeadquartersMarcel Dekker, 270 Madison Avenue, New York, NY
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Special Sales/Professional Marketing at the headquarters address
above.Copyright 2005 by Marcel Dekker. All Rights Reserved.Neither
this book nor any part may be reproduced or transmitted in any form
or by any means,electronic or mechanical, including photocopying,
microlming, and recording, or by anyinformation storage and
retrieval system, without permission in writing from the
publisher.Current printing (last digit):10 9 8 7 6 5 4 3 2 1PRINTED
IN THE UNITED STATES OF AMERICACopyright 2005 by Marcel Dekker. All
Rights Reserved.PrefaceThe purpose of the 1st edition of this
handbook was to present a condensed butcomprehensive review of the
methods used for syntheses and modifications of the mostimportant
classes of polymers. The good acceptance of this handbook by the
internationalscientific community has prompted the publisher to
launch a second edition updating theliterature up to the year 2000
for the most widely studied groups of polymers. The editorshope
that this 2nd edition will provide the chemists with an useful
first hand informationon new preparative methods in the field of
polymer science.Copyright 2005 by Marcel Dekker. All Rights
Reserved.ContentsPrefaceList of Contributors1. PolyolefinsWalter
Kaminsky2. Polystyrenes and Other Aromatic Poly(vinyl
compound)sOskar Nuyken3. Poly(vinyl ether)s, Poly(vinyl ester)s,
andPoly(vinyl halogenide)sOskar Nuyken, Harald Braun and James
Crivello4. Polymers of Acrylic Acid, Methacrylic Acid, Maleic Acid
andtheir DerivativesOskar Nuyken5. Polymeric DienesWalter Kaminsky
and B. Hinrichs6. Metathesis Polymerization of CycloolefinsUlrich
Frenzel, Bettina K. M. Muller and Oskar Nuyken7. Aromatic
PolyethersHans R. KricheldorfCopyright 2005 by Marcel Dekker. All
Rights Reserved.8. PolyurethanesZoran S. Petrovic9.
PolyimidesJavier de Abajo and Jose G. de la Campa10. Poly(vinyl
aldehyde)s, Poly(vinyl ketone)s, andPhosphorus-Containing Vinyl
PolymersOskar Nuyken11. Metal-Containing MacromoleculesDieter
Wohrle12. Conducting PolymersHerbert Naarmann13. Photoconductive
PolymersP. Strohriegl and J. V. Grazulevicius14. Polymers for
Organic Light Emitting Devices/Diodes (OLEDs)O. Nuyken, E. Bacher,
M. Rojahn, V. Wiederhirn,R. Weberskirch and K. Meerholz15.
Crosslinking and Polymer NetworksManfred L. Hallensleben16.
Biodegradable Polymers for Biomedical ApplicationsSamuel J.
Huang17. Controlled/Living Radical PolymerizationKrzysztof
Matyjaszewski and James SpanswickCopyright 2005 by Marcel Dekker.
All Rights Reserved.List of ContributorsE. Bacher, Technische
Universita t Mu nchen, Garching, GermanyHarald Braun, Technische
Universita t Mu nchen, Garching, GermanyJames Crivello, Rensselaer
Polytechnic Institute, Troy, New YorkJavier de Abajo, Institute of
Polymer Science and Technology, Madrid, SpainJose G. de la Campa,
Institute of Polymer Science and Technology, Madrid, SpainUlrich
Frenzel, Technische Universita t Mu nchen, Garching, GermanyJ. V.
Grazulevicius, Kaunas University of Technology, Kaunas,
LithuaniaManfred L. Hallensleben, Institut fu r Makromolekulare
Chemie, Universita t Hannover,Hannover, GermanyB. Hinrichs,
University of Hamburg, Hamburg, GermanySamuel J. Huang, Institute
of Materials Science, University of Connecticut,
Storrs,ConnecticutWalter Kaminsky, Institute of Technical and
Macromolecular Chemistry, University ofHamburg, Hamburg,
GermanyHans R. Kricheldorf, Institute of Technical and
Macromolecular Chemistry, University ofHamburg, Hamburg,
GermanyKrzysztof Matyjaszewski, Center for Macromolecular
Engineering, Carnegie MellonUniversity, Pittsburgh,
PennsylvaniaBettina K. M. Mu ller, Technische Universita t Mu
nchen, Garching, GermanyHerbert Naarmann, (emerit) BASF AG
LudwigshafenOskar Nuyken, Technische Universita t Mu nchen,
Garching, GermanyCopyright 2005 by Marcel Dekker. All Rights
Reserved.Zoran S. Petrovic , Pittsburg State University, Kansas
Polymer Research Center, Pittsburg,KansasM. Rojahn, Technische
Universita t Mu nchen, Garching, GermanyJames Spanswick, Center for
Macromolecular Engineering, Carnegie Mellon University,Pittsburgh,
PennsylvaniaP. Strohriegl, Universita t Bayreuth, Makromolekulare
Chemie I, and BayreutherInstitut fu r Makromoleku lforschung
(BIMF), Bayreuth, GermanyR. Weberskirch, Technische Universita t Mu
nchen, Garching, GermanyV. Wiederhirn, Technische Universita t Mu
nchen, Garching, GermanyDieter Wo hrle, University of Bremen,
Bremen, GermanyCopyright 2005 by Marcel Dekker. All Rights
Reserved.1PolyolefinsWalter KaminskyUniversity of Hamburg, Hamburg,
GermanyI. INTRODUCTIONThe polyolens production has increased
rapidly in the 40 years to make polyolens themajor tonnage plastics
material worldwide. In 2003, 55 million tons of polyethene and
38million t/a polypropene were produced [1]. These products are
used for packing material,receptacles, pipes, domestic articles,
foils, and bers. Polyolens consist of carbon andhydrogen atoms only
and the monomers are easily available. Considering
environmentalaspects, clean disposal can be achieved by burning or
by pyrolysis, for instance. Burninginvolves conversion to CO2 and
H2O, exclusively.By copolymerization of ethene and propene with
higher n-olens, cyclic olens, orpolar monomers, product properties
can be varied considerably, thus extending the eld ofpossible
applications. For this reason terpolymers of the ethene/propene
n-olen type arethe polymers with the greatest potential. Ethene can
be polymerized radically or by meansof organometallic catalysts. In
the case of polyisobutylene a cationic polymerizationmechanism
takes place. All other olens (propene, 1-butene, 4-methylpentene)
are poly-merized with organometallic catalysts. The existence of
several types of polyethene as wellas blends of these polymers
provides the designer with an unusual versatility in
resinspecications. Thus polyethene technology has progressed from
its dependence on onelow-density polymer to numerous linear
polymers, copolymers, and blends that will extendthe use of
polyethene to many previously unacceptable applications.Polypropene
also shows versatility and unusual growth potential. The
mainadvantage is improved susceptibility to degradation by outdoor
exposure. The increasein the mass of polypropene used for the
production of bers and laments is inive of theversatility of this
polymer.Synthetic polyolens were rst synthetisized by decomposition
of diazomethane [2].With the exception of polyisobutylene, these
polymers were essentially laboratorycuriosities. They could not be
produced economically. The situation changed with thediscovery of
the high pressure process by Fawcett and Gibson (ICI) in 1930:
ethenewas polymerized by radical compounds [3]. To achieve a
sucient polymerization rate,a pressure of more than 100 MPa is
necessary. First produced in 1931, the low densitypolyethene (LDPE)
was used as isolation material in cables.Due to its low melting
point of less than 100
C LDPE could not be appliedto the production of domestic
articles that would be used in contact with hot water.Copyright
2005 by Marcel Dekker. All Rights Reserved.Important progress for a
broader application was made when Hogan and Banks [4](Phillips
Petroleum) and Ziegler et al. [5] found that ethene can be
polymerized by meansof activated transition metal catalyst systems.
In this case the high density polyethene(HDPE), a product
consisting of highly linear polymer chains, softens above 100
C.Hogan polymerized ethene using a nickel oxide catalyst and
later a chromium salt on analumina-silica support. Zletz [6] used
molybdenum oxide on alumina in 1951 (StandardOil); Fischer [7] used
aluminum chloride along with titanium tetrauoride (BASF 1953)for
the production of high-density polyethene. The latter catalyst has
poor activityand was never used commercially. Zieglers [5] use of
transition metal halogenides andaluminum organic compounds and the
work of Natta [8] in applying this catalyst systemfor the synthesis
of stereoregular polyolens were probably the two most
importantachievements in the area of catalysis and polymer
chemistry in the last 50 years.They led to the development of a new
branch of the chemical industry and to a largeproduction volume of
such crystalline polyolens as HDPE, isotactic
polypropene,ethane-propene rubbers, and isotactic poly(l-butene).
For their works, Ziegler and Nattawere awarded the Nobel Prize in
1963. The initial research of Ziegler and Natta wasfollowed by an
explosion of scientic papers and patents covering most aspects
ofolen polymerization, catalyst synthesis, and polymerization
kinetics as well as thestructural, chemical, physical, and
technological characteristics of stereoregular poly-olens and olen
copolymers. Since that rst publication, more than 20 000 papersand
patents have been published on subjects related to that eld.
Several books andreviews giving detailed information on the
subjects of these papers have been published[919].The rst
generation of ZieglerNatta catalysts, based on TiCl3/AlEt2Cl,
wascharacterized by low polymerization activity. Thus a large
amount of catalyst was needed,which contaminated the raw polymer. A
washing step that increased production costs wasnecessary. A second
generation of ZieglerNatta catalysts followed, in which the
transitionmetal compound is attached to a support (MgCl2, SiO2,
Al2O3). These supported catalystsare of high activity. The product
contains only traces of residues, which may remain in thepolymer.
Most ZieglerNatta catalysts are heterogeneous. More recent
developmentsshow that homogeneous catalyst systems based on
metallocene-alumoxane and othersingle-site catalysts can also be
applied to olen polymerization [2023]. These systems areeasy to
handle by laboratory standards, and show highest activities and an
extended rangeof polymer products.The mechanism of ZieglerNatta
catalysis is not known in detail. A two-stepmechanism is commonly
accepted: First, the monomer is adsorbed (p-complex bonded) atthe
transition metal. During this step the monomer may be activated by
the congurationestablished in the active complex. Second, the
activated monomer is inserted into themetalcarbon bond. In this
sequence the metal-organic polymerization resembles whatnature
accomplishes with enzymes.ZieglerNatta catalysts are highly
sensitive, to oxygen, moisture, and a large numberof chemical
compounds. Therefore, very stringent requirements of reagent purity
andutmost care in all manipulations of catalysts and polymerization
reactions themselves aremandatory for achieving experimental
reproducibility and reliability. Special care must betaken to
ensure that solvents and monomers are extremely pure. Alkanes and
aromaticcompounds have no substantial eect on the polymerization
and can therefore be used assolvents. Secondary alkenes usually
have a negative eect on polymerization rates, andalkynes, allenes
(1,2-butadiene), and conjugated dienes are known to act as
catalystpoisons, as they tend to form stable complexes.Copyright
2005 by Marcel Dekker. All Rights Reserved.Almost all polar
substances exert a strong negative inuence on the
polymerization.COS and hydrogen sulde, particularly, are considered
to be strong catalyst poisons, ofwhich traces of more than 0.2 vol
ppm aect a catalysts activity. Neither the solvent northe gaseous
monomer should contain water, carbon dioxide, alcohols, or other
polarsubstances in excess of 5 ppm. Purication may be carried out
by means of molecularsieves.The termination of the polymerization
reaction by the addition of carbon monoxideis used to determine the
active centers (sites) of the catalyst. Hydrogen is known to
slightlyreduce the catalysts activity. Yet it is commonly used as
an important regulator to lowerthe molecular weights of the
polyethene or polypropene produced.II. POLYETHENEThe polymerization
of ethene can be released by radical initiators at high pressures
aswell as by organometallic coordination catalysts. The
polymerization can be carried outeither in solution or in bulk. For
pressures above 100 MPa, ethene itself acts as a solvent.Both low-
and high-molecular-weight polymers up to 106g/mol can be
synthesized byeither organometallic coordination or high pressure
radical polymerization. The structureof the polyethene diers with
the two methods. Radical initiators give more-or-lessbranched
polymer chains, whereas organometallic coordination catalysts
synthesize linearmolecules.A. Radical PolymerizationSince the
polymerization of ethene develops excess heat, radical
polymerization on alaboratory scale is best carried out in a
discontinuous, stirred batch reactor. On a technicalscale, however,
column reactors are widely used. The necessary pressure is
generallykept around 180 to 350 MPa and the temperature ranges from
180 to 350
C [2429].Solvent polymerization can be performed at substantial
lower pressures and at tem-peratures below 100
C. The high-pressure polymerization of ethene proceeds via a
radicalchain mechanism. In this case chain propagation is regulated
by disproportionation orrecombination.123Copyright 2005 by Marcel
Dekker. All Rights Reserved.The rate constants for chain
propagation and chain termination at 130
and180 MPa can be specied as follows [30]:Mp 5:93 103 L mol1s1Mt
2 108 L mol1s1Intermolecular and intramolecular chain transfer take
place simultaneously. Thisdetermines the structure of the
polyethene. Intermolecular chain transfer results in longexible
side chains but is not as frequent as intramolecular chain
transfer, from whichshort side chains mainly of the butyl type
arise [31,32].Intermolecular chain transfer:45Intramolecular chain
transfer:67Radically created polyethene typically contains a total
number of 10 to 50 branchesper 1000 C atoms. Of these, 10% are
ethyl, 50% are butyl, and 40% are longer sidechains. With the
simplied formulars (6) and (7), not all branches observed could
beexplained [33,34]. A high-pressure stainless steal autoclave (0.1
to 0.51 MPa) equippedwith an inlet and outlet valve, temperature
conductor, stirrer, and bursting disk is used forthe synthesis.
Best performance is obtained with an electrically heated autoclave
[3541].To prevent self-degeneration, the temperature should not
exceed 350
C. Etheneand intitiator are introduced by a piston or membrane
compressor. An in-built sapphirewindow makes it possible to observe
the phase relation. After the polymerization isnished, the reaction
mixture is released in two steps. Temperature increases are due toa
negative JouleThompson eect. At 26 MPa, ethene separates from the
250
C hotpolymer melt. After further decompression down to normal
pressure, the residual etheneis removed [4246]. Reaction pressure
and temperature are of great importance forthe molecular weight
average, molecular weight distribution, and structure of
thepolymer. Generally, one can say that with increasing reaction
pressure the weight averageincreases, the distribution becomes
narrower, and short- and long-chain branching bothdecrease
[47].Copyright 2005 by Marcel Dekker. All Rights Reserved.Oxygen or
peroxides are used as the initiators. Initiation is very similar to
thatin many other free-radical polymerizations at dierent
temperatures according to theirhalf-live times (Table 1). The
pressure dependence is low. Ethene polymerization can alsobe
started by ion radiation [4851]. The desired molecular weight is
best adjusted by theuse of chain transfer reagents. In this case
hydrocarbons, alcohols, aldehydes, ketones, andesters are suitable
[52,53].Table 2 shows polymerization conditions for the
high-pressure process and density,molecular weight, and weight
distribution of the polyethene (LDPE). Bunn [54] wasthe rst to
study the structure of polyethene by x-ray. At a time when there
was stillconsiderable debate about the character of macromolecules,
the demonstration thatwholly synthetic and crystalline polyethene
has a simple close-packed structure in whichthe bond angles and
bond lengths are identical to those found in small molecules
suchTable 1 Peroxides as initiators for the high-pressure
polymerization of ethene.Peroxide Molecular weight Half-time period
of 1 minby a polymerizationtemperature (
C)(H3C)3-COOC(CH3)3 146.2 190174.2 110146 115216.3 130286.4
120230.3 160246.4 100194.2 120194.2 170234.3 90Copyright 2005 by
Marcel Dekker. All Rights Reserved.as C36H74 [5557], strengthened
the strictly logical view that macromolecules are amultiplication
of smaller elements joined by covalent bonds. LDPE crystallizes in
singlelamellae with a thickness of 5.0 to 5.5 nm and a distance
between lamellae of 7.0 nm whichis lled by an amorphous phase. The
crystallinity ranges from 58 to 62%.Recently, transition metals and
organometallics have gained great interest ascatalysts for the
polymerization of olens [58,59] under high pressure. High
pressurechanges the properties of polyethene in a wide range and
increases the productivityof the catalysts. Catalyst activity at
temperatures higher than 150
C is controlledprimarily by polymerization and deactivation.
This fact can be expressed by the practicalnotion of catalyst life
time, which is quite similar to that used with free-radical
initiators.The deactivation reaction at an aluminum alkyl
concentration below 5 105mol/lseems to be rst order reaction [60].
Thus for various catalyst-activator systems, theapproximate
polymerization times needed in a continuous reactor to ensure the
best useof catalyst between 150 to 300
C are between several seconds and a few minutes.Several studies
have been conducted to obtain ZieglerNatta catalysts with good
thermalstability. The major problem to be solved is the reduction
of the transition metal(e.g., TiCl3) by the cocatalyst, which may
be aluminum dialkyl halide, alkylsiloxyalanes[60], or aluminoxane
[59].Luft and colleagues [61,62] investigated high-pressure
polymerization in the presenceof heterogeneous catalysts consisting
of titanium supported on magnesium dichlorideor with homogeneous
metallocene catalysts. With homogeneous catalysts, a pressure of150
MPa (80 to 210
C) results in a productivity of 700 to 1800 kg PE/cat,
molecularweights up to 110 000 g/mol, and a polydispersity of 5 to
10, with heterogeneous catalysts,whereas the productivity is 3000
to 7000 kg PE/cat, molecular weight up to 70 000 g/mol,and the
polydispersity 2.B. Coordination CatalystsEthene polymerization by
the use of catalysts based on transition metals gives a
polymerexhibiting a greater density and crystallinity than the
polymer obtained via radicalpolymerization. Coordination catalysts
for the polymerization of ethene can be of verydierent nature. They
all contain a transition metal that is soluble or insoluble
inhydrocarbons, supported by silica, alumina, or magnesium chloride
[5,63]. In most casescocatalysts are used as activators. These are
organometallic or hydride compounds ofgroup I to III elements; for
example, AlEt3, AlEt2Cl, Al(i-Bu)3, GaEt3, ZnEt2, n-BuLi,amyl Na
[64]. Three groups are used for catalysis:1. Catalysts based on
titanium or zirconium halogenides or hydrides in connectionwith
aluminum organic compound (Ziegler catalysts)Table 2 Polymerization
conditions and product properties of high-pressure polyethene
(LDPE).Pressure(MPa)Temp.(
C)Regulator(propane) (wt%)Density(g/cm3)Molecularweight
MFIDistribution165 235 1.6 0.919 1.3 20205 290 1.0 0.915 17.0 10300
250 3.9 0.925 2.0 10Source: Ref. 29.Copyright 2005 by Marcel
Dekker. All Rights Reserved.2. Catalysts based on chromium
compounds supported by silica or aluminawithout a coactivator
(Phillips catalysts)3. Homogeneous catalysts based on metallocenes
in connection with aluminoxaneor other single site catalysts such
as nickel ylid, nickel diimine, palladium, iron orcobalt
complexes.Currently, mainly Ziegler and Phillips catalysts as well
as some metallocene catalysts[63] are generally used
technically.Three dierent processes are possible: the slurry
process, the gas phase process, andthe solvent process [6568]:1.
Slurry process. For the slurry process hydrocarbons such as
isobutane,hexane, n-alkane are used in which the polyethene is
insoluble. The polymer-ization temperature ranges from 70 to 90
C, with ethene pressure varyingbetween 0.7 and 3 MPa. The
polymerization time is 1 to 3 h and the yield is95 to 98%. The
polyethene produced is obtained in the form of fine particles inthe
diluent and can be separated by filtration. The molecular weight
can becontrolled by hydrogen; the molecular weight distribution is
regulated byvariation of the catalyst design or by polymerization
in several steps undervarying conditions [6973]. The best
preparation takes place in stirred vessels orloop reactors.In some
processes the polymerization is carried out in a series of
cascadereactors to allow the variation of hydrogen concentration
through the operatingsteps in order to control the distribution of
the molecular weights. The slurrycontains about 40% by weight
polymer. In some processes the diluent isrecovered after
centrifugation and recycled without purification.2. Gas phase
polymerization. Compared to the slurry process, polymerizationin
the gas phase has the advantage that no diluent is used which
simplifiesthe process [7476]. A fluidized bed that can be stirred
is used with supportedcatalysts. The polymerization is carried out
at 2 to 2.5 MPa and 85 to 100
C.The ethene monomer circulates, thus removing the heat of
polymerizationand fluidizing the bed. To keep the temperature at
values below 100
C, gasconversion is maintained at 2 to 3 per pass. The polymer
is withdrawn periodi-cally from the reactor.3. Solvent
polymerization. For the synthesis of low-molecular-weight
poly-ethene, the solvent process can be used [77,78]. Cyclohexane
or anotherappropriate solvent is heated to 140 to 150
C. After addition of the catalyst,very rapid polymerization
starts. The vessel must be cooled indirectly by water.Temperature
control is also achieved via the ethene pressure, which can
bevaried between 0.7 and 7 MPa.In contrast to high-pressure
polyethene with long-chain branches, the polyetheneproduced with
coordination catalysts has a more or less linear structure (Figure
1) [79].A good characterization of
high-molecular-weight-polyethenes gives the melt
rheologicalbehaviour [80] (shear viscosity, shear compliance). The
density of the homopolyethenesis higher but it can be lowered by
copolymerization. Polymers produced with unmodi-ed Ziegler
catalysts showed extremely high molecular weight and broad
distribution[81]. In fact, there is no reason for any termination
step, except for consecutivereaction. Equations (8) to (11) show
simplied chain propagation and chain terminationsteps
[11].Copyright 2005 by Marcel Dekker. All Rights Reserved.Chain
propagation:8Chain termination:(a) By b elimination with H transfer
to monomer9(b) By hydrogenation10Figure 1 Comparison of various
polyethenes.Copyright 2005 by Marcel Dekker. All Rights
Reserved.(c) By b elimination forming hydride11Termination via
hydrogenation gives saturated polymer and metal hydride.
Thetermination of a growing molecule by an a-elimination step forms
a polymer with anolenic end group and a metal hydride. In addition,
an exchange reaction with etheneforming a polymer with an olenic
end group and an ethyl metal is observed.1. Titanium Chloride-Based
CatalystsThe rst catalyst used by Ziegler et al. [5,82] for the
polymerization of ethene was amixture of TiCl4 and Al(C2H5)3, each
of which is soluble in hydrocarbons. In combinationthey form an
olive-colored insoluble complex that is very unstable. Its behavior
is verysensitive to a number of experimental parameters, such as
Al/Ti ratio, temperature andtime of mixing of all components, and
absolute and relative concentrations of reactants[83]. After
complexation, TiCl4 is reduced by a very specic reduction process.
Thisreduction involves alkylation of TiCl4 with aluminum alkyl
molecules followed by adealkylation reduction to a trivalent
state:Complexation: TiCl4AlEt3 TiCl4 AlEt3 12Alkylation:
TiCl4:AlEt3 EtTiCl3 AlEt2Cl 13Reduction: 2EtTiCl3 2TiCl3 Et2
14Under drastic conditions, TiCl3 can be reduced to TiCl2 in a
similar way. The actualTiCl3 product is a compound alloyed with
small amounts of AlCl3 and probably somechemisorbed AlEt2Cl. The
mechanistic process is very complex and not well understood.Instead
of Al(C2H5)3, also Al(C2H5)2Cl, Al2(C2H5)3Cl3, or Al(i-Bu)3 could
be used.These systems, called rst-generation catalysts, are used
for the classic process of olenpolymerization. In practice,
however, the low activity made it necessary to deactivatethe
catalyst after polymerization, remove the diluent, and then remove
the residues ofcatalyst with HCl and alcohols. This treatment is
followed by washing the polyethenewith water and drying it with
steam. Purication of the diluent recovered and feedbackof the
monomer after a purication step involved further complications. The
costs ofthese steps reduced the advantage of the low-pressure
polymerization process. Therefore,it was one of the main tasks of
polyolen research to develop new catalysts (secondgeneration
catalysts) that are more active, and can therefore remain in the
polymerwithout any disadvantage to the properties (Table 3) [84].
The process is just as sensitiveto perturbation, it is cheaper, and
energy consumption as well as environmental loadingare lower. It is
also possible to return to the polymerization vessel diluent
containinga high amount of the aluminum alkyl. The second
generation is based on TiCl3compounds or supported catalysts
MgCl2/TiCl4/Al(C2H5)3 or CrO3(SiO2) (Phillips).Copyright 2005 by
Marcel Dekker. All Rights Reserved.2. Unsupported Titanium
CatalystsThere is a very large number of dierent combinations of
aluminum alkyls and titaniumsalts to make high mileage catalysts
for ethene polymerization, such as a-TiCl3AlEt3,AlEt2Cl, Al(i-Bu)3,
and Ti(III)alkanolate-chloride Al(i-hexyl)3 [85]. TiCl3 exists in
fourcrystalline modications, the a, b, g, and d forms [86]. The
composition of these TiCl3scan be as simple as one Ti for as many
as three Cl, or they can have a more complexstructure whereby a
second metal is cocrystallized as an alloy in the TiCl3. The
particularmethod of reduction determines both composition and
crystalline modication. a-TiCl3can be synthesized by reduction of
TiCl4 with H2 at elevated temperatures (500 to 800
C)or with aluminum powder at lower temperatures (about 250
C); in this case the a-TiCl3contains Al cations [87]. More
active are g- and d-TiCl3 modications. They are formedby heating
the a-TiCl3 to 100 or 200
C. The preferred a-TiCl3 contains Al and issynthesized by
reducing TiCl4 with about 1/3 part AlEt3 or 1 part AlEt2Cl. A
modemTiCl3 catalyst has a density of 2.065 g/cm3, a bulk density of
0.82, a specic surface area(BET) of 29 m2/g, and a particle size of
10 to 100 mm. The polymerization activity is in thevicinity of 500
Lmol1s1[88].3. Supported CatalystsMgCl2/TiCl4 catalysts. Good
progress in increasing the polymerization activity was madewith the
discovery of the MgCl2/TiCl4-based catalysts [89]. Instead of
MgCl2, Mg(OH)Cl,MgRCl, or MgR2 [9094] can be used. The
polymerization activity goes up to10 000 Lmol1s1. At this high
activity the catalyst can remain in the polyethene. Forexample, the
specic volume (BET) of the catalystis 60 m2/g [95]. The high
activity isaccomplished by increasing the ethene pressure. The
dependence is not linear as it wasfor rst-generation catalysts, and
the morphology is also dierent. The polyethene has acobweb-like
structure, whereas rst generation catalysts produced a worm-like
structure[90,91]. The cobweb structure is caused by the fact that
polymerization begins at thesurface of the catalyst particle. The
particle is held together by the polymer. Whilepolymerization is in
progress, the particle grows rapidly and parts of it break.
Cobwebstructures are formed by this fast stretching process of the
polyethene.Table 3 Comparison of various catalyst processes for
ethene polymerization.First generation Second generationCatalyst
preparation Catalyst preparationPolymerization
PolymerizationLimited inuence to molecular weight andweight
distributionGreat variation of molecular weight andweight
distributionCatalyst deactivation with alcoholFiltration
FiltrationWashing with water (HCl), wastewater
treatment,purication, and drying of diluentFeedback of
diluentDrying of PE Drying of PEFinishing FinishingThermal
degradation of molecular weight, blendingStabilization
StabilizationSource: Ref. 84.Copyright 2005 by Marcel Dekker. All
Rights Reserved.It is known that in the case of these supported
catalysts the higher activity is linkedto a higher concentration of
active titanium. In contrast to rst-generation catalysts inwhich
only 0.1 to 1% of all titanium atoms form active sites, in
supported catalysts 20 to80% of them are involved in the formation
of active sites [97,98].Solvay workers [99] have investigated
extensively the supported Mg(OH)Cl/TiCl4/AlEt3 catalyst and related
systems including MgSO4, MgOSiO2, and MgO. It is not clearwhether
all of the Ti centers in the supported catalysts are isolated. The
high activitysuggests the incorporation of small TiCl3 crystallites
into the Mg(OH)Cl. Fink andKinkelin [100] prepared a high-activity
catalyst by combination of MgH2 and TiCl4.The MgH2 has a much
greater surface area (90 m2/g). It reacts with the TiCl4 underthe
evolution of hydrogene. By 30
C and 2 bar ethene pressure, 110 kg of PE per gram ofTi could be
obtained.4. Phillips CatalystThe widely investigated Phillips
catalyst, which is alkyl free, can be prepared by impreg-nating a
silica-alumina (87:13 composition [101103] or a silica support with
an aqueoussolution of CrO3). High surface supports with about 400
to 600 g/m2are used [104]. Afterthe water is removed, the powdery
catalyst is uidized and activated by a stream of dry airat
temperatures of 400 to 800
C to remove the bound water. The impregnated catalystscontain 1
to 5 wt% chromium oxides. When this catalyst is heated in the
presence ofcarbon monoxide, a more active catalyst is obtained
[105]. The Phillips catalyst specicallycatalyzes the polymerization
of ethene to high-density polyethene. To obtain polyethene oflower
crystallinity, copolymers with known amounts of an a-olen, usually
several percentof 1-butene can be synthesized. The polymerization
can be carried out by a solution,slurry, or gas-phase (vapor phase)
process.The chromium oxide-silica is inactive for polymerizing
ethylene at low temperaturesbut becomes active as the temperature
is increased from 196
C (the melting point forCrO3) to 400
C. Interactions of chromium oxide with SiO2 and Al2O3 take
place.Hogan [103] calculated that for a silica support of 600 m2/g
and about 5% Cr(VI),the average distance between adjacent Cr atoms
is 10 A. This corresponds to the acceptedpopulation of silanol
groups on silica after calcination. The structures (15) and (16)
areproposed:1516Copyright 2005 by Marcel Dekker. All Rights
Reserved.It has been calculated that between 0.1 and 0.4 wt% of the
total chromiumforms active centers [105]. A dicult question relates
to the valences of chromium in theactive sites. Valences of II,
III, IV, V, and VI have been established [106]. Because of thesmall
number of total chromium atoms that are active centers, it has not
been possible tounequivocally assign the active valence [107,108].
Krauss and Hums [109] concluded thatthe reduction of hexavalent
chromium centers linked to support produced coordinatelyunsaturated
Cr(II) surface compounds. A speciality of the Phillips catalyst is
that there isno inuence of hydrogen to control the molecular weight
of the polyethylene. Only byhigher activation temperatures can the
molecular weight be lowered.5. Homogeneous (Single Site)
CatalystsAmong the great number of Ziegler catalysts, homogeneous
systems have beenpreferentially studied in order to understand the
elementary steps of the polymerizationwhich is simpler in soluble
systems than in heterogeneous systems. The situationhas changed
since in recent years homogeneous catalyst based on metallocene
andaluminoxane [12,110], nickel and palladium diimin complexes
[111], and iron and cobaltcompounds were discovered which are also
very interesting for industrial and laboratorysynthesis. Some
special polymers can only be synthesized with these catalysts.In
comparison to Ziegler systems, metallocene catalysts represent a
great develop-ment: they are soluble in hydrocarbons, show only one
type of active site and theirchemical structure can be easily
changed. These properties allow one to predict accuratelythe
properties of the resulting polyolens by knowing the structure of
the catalyst usedduring their manufacture and to control the
resulting molecular weight and distribution,comonomer content and
tacticity by careful selection of the appropriate reactor
condi-tions. In addition, their catalytic activity is 10100 times
higher than that of the classicalZieglerNatta systems.Metallocenes,
in combination with the conventional aluminum alkyl cocatalysts
usedin Ziegler systems, are indeed capable of polymerising ethene,
but only at a very lowactivity. Only with the discovery and
application of methylaluminoxane (MAO) it waspossible to enhance
the activity, surprisingly, by a factor of 10 000 [113]. Therefore,
MAOplays a crucial part in the catalysis with metallocenes.Kinetic
studies and the application of various methods have helped to dene
thenature of the active centers, to explain the aging eects of
Ziegler catalysts, to establishthe mechanism of interaction with
olens, and to obtain quantitative evidence of someelementary steps
[9,112115]. It is necessary to dierentiate between the soluble
catalystsystem itself and the polymerization system. Unfortunately,
the well-dened bis(cyclo-pentadienyl)titanium system is soluble,
but it becomes heterogeneous when polyethyleneis formed [116].The
polymerization of olens, promoted by homogeneous Ziegler catalysts
basedon biscyclopentadienyltitanium(IV) or analogous compounds and
aluminum alkyls,is accompanied by a series of other reactions that
greatly complicate the kinetic inter-pretation of the
polymerization process:17Copyright 2005 by Marcel Dekker. All
Rights Reserved.181920Concomitant with continued olen insertion
into the metalcarbon bond of thetransition metal aluminum complex,
alkyl exchange and hydrogen-transfer reactionsare observed. Whereas
the normal reduction mechanism for transition metal
organiccomplexes is initiated by release of olens with formation of
a hydride followed by hydridetransfer to an alkyl group, a reverse
reaction takes place in the case of some titaniumand zirconium
acompounds. A dimetalloalkane is formed by the release of ethane.
Insecond step, ethene is evolved from the
dimetalloalkane:TiIVCH2CH2TiIV ! CH2CH2 2TiIII 21leaving two
reduced metal atoms. Some of the aging processes occurring with
homo-geneous and heterogeneous Ziegler catalysts can be explained
with the aid of these sidereactions.Table 4 summarizes important
homogeneous Ziegler catalysts. The best known sys-tems are based on
bis(cyclopentadienyl)titanium(IV),
bis(cyclopentadienyl)zirconium(IV),terabenzyltitanium, vanadium
chloride, allyl metal, or chromium acetylacetonate
withtrialkylaluminum, alkylaluminum halides, or aluminoxanes.
Breslow [126] discovered thatbis(cyclopentadienyl)titanium(IV)
compounds, which are easily soluble in aromatichydrocarbons, could
be used instead of titanium tetrachloride as the transition
metalcompound together with aluminum alkyls for ethene
polymerization. Subsequent researchon this and other systems with
various alkyl groups has been conducted by Natta [127],Belov et al.
[128,129], Patat and Sinn [130], Shilov [131], Henrici-Olive and
Olive [132],Reichert and Schoetter [133], and Fink et al.
[134,135]. With respect to the kinetics ofpolymerization and side
reactions, this soluble system is probably the one that is
bestunderstood. It is found that the polymerization takes place
primarily if the titanium existsas titanium(IV) [136,137].
According to Henrici-Olive and Olive [138], the speedof
polymerization decreases with increasing intensity of ESR signals
of the developingtitanium(III) compound.The increase in length of
the polymer chain occurs by insertion of the monomer in toa
metalcarbon bond of the active complex. Dyachkovskii et al. [139]
and Eisch et al. [140]were the rst to believe, based on kinetic
measurements and synthesis, that the insertiontakes place on a
titanium cation. An ion of the type (C5H5)2Ti-R, derived
fromCopyright 2005 by Marcel Dekker. All Rights Reserved.complexing
and dissociation,C5H52TiRCl AlRCl2 C5H52TiRCl AlRCl2 22C5H52TiRCl
AlRCl2 C5H52TiRCl3
AlRCl3
23could be the active species of polymerization. Sinn and Patat
[137] drew attention to theelectron-decient character of those
main-group alkyls that aord complexes with thetitanium compound.
Fink and co-workers [141] showed by 13C-NMR spectroscopy
with13C-enriched ethene at low temperatures (where no alkyl
exchange was observed) thatin higher halogenated systems, insertion
of the ethene takes place only into a titaniumcarbon bond.At low
polymerization temperatures with benzene as a solvent, Hocker and
Saeki[142] could prepare polyethene with a molecular weight
distribution MW/Mn1.07 usingthe bis(cyclopentadienyl)titanium
dichloride/diethylaluminum chloride system. The mole-cular weight
could be varied in a wide range by changing the polymerization
temperature.Using ally4Zr(allylZrBr3) at a polymerization
temperature of 160
C (80
C) yields poly-ethene with a density of 0.966 g/cm, Mnof 10,500,
(700), 3.0 CH3groups per 1000
Cand 0.4vinyl groups. The benzene- and allyl-containing
transition metals are working without anycocatalyst and therefore
are alkyl free. If transition metal organometallic compounds suchas
Cr(allyl)3, Zr(allyl)4, Zr(benzyl)4, Ti(benzyl)4, and
Cr(cyclopentadienyl)2 are supportedon Al2O3 Or SiO2, the activity
increases by a factor of more than 100 [124,143].Apparently,
soluble catalysts are obtained by reaction of Ti(OR)4 with AlR3
[144].High-molecular-weight polyethene is obtained in variable
amounts, with Al/Ti ratiosranging between 10 and 50. Similar
results are attained by replacing titanium alkoxideby Ti(NR2)4
[145]. Soluble catalytic systems are also obtained by reaction of
Ti(acac)3[146] and Cr(acac)3 [147] with AlEt3 as well as by
reaction of Cr(acac)3 and VO(acac)2 withAlEt2Cl in the presence of
triethyl phosphite [121]. With vanadium catalysts the
activityreaches its maximum at Al/V ratio 50. Under these
conditions up to 67% vanadium is inthe bivalent oxidation state.
Bivalent and trivalent compounds will be active.Table 4 Homogeneous
catalysts for ethene polymerization.System Transition metal(M)
compoundPolymerizationtemperature (
C)NormalizedactivityCatalystyieldRefsCp2TiCl2/AlMe2Cla1:2.51:6
30 40200 117Cp2TiCl2/AlMe2Cl/H2O 1:6:3 30 2000 117Cp2TiCl2/AlEt2Cl
1:2 15 745 118Cp2TiMe2/MAO 1:105.5 10220 35 000 >15 000
110Cp2TiMe2/MAO 1:100 20 200 >5 000 119Cp2ZrCl2/MAO 1:1000 70
400 000 >10 000 120VO(acac)2/Et2AlCl/activator 1:50 20 180
121Cp2VCl2/Me2AlCl 1:5 50 13 122Zr(allyl)4 80 2.0Hf(allyl)4 160
0.6Cr(ally)3 80 0.3 123Cr(acac)3/EtAlCl 1:300 20 150 121Ti(benzyl)4
20(80) 8 103(0.2) 124,125Ti(benzyl)3Cl 20 0.4
124,125Ti(benzyl)4Copyright 2005 by Marcel Dekker. All Rights
Reserved.6. Aluminoxane as CocatalystsThe use of metallocenes and
alumoxane as cocatalyst results in extremely high poly-merization
activities (see Tables 4 and 5). This system can easily be used on
a laboratoryscale. The methylalumoxane (MAO) is prepared by careful
treatment of trimethylalumi-num with water [148]:24MAO is a
compound in which aluminum and oxygen atoms are arranged
alternatelyand free valences are saturated by methyl substituents.
It is gained by careful partialhydrolysis of trimethylaluminum and,
according to investigations by Sinn [149] andBarron [150], it
consists mainly of units of the basic structure [Al4O3Me6], which
containsfour aluminum, three oxygen atoms and six methyl groups. As
the aluminum atoms inthis structure are co-ordinatively
unsaturated, the basic units (mostly four) join togetherforming
clusters and cages. These have molecular weights from 1200 to 1600
and aresoluble in hydrocarbons.If metallocenes, especially
zirconocenes but also titanocenes, hafnocenes and othertransition
metal compounds (Figure 2) are treated with MAO, then catalysts are
acquiredthat allow the polymerization of up to 100 tons of ethene
per g of zirconium [151153].At such high activities the catalyst
can remain in the product. The insertion time (for theinsertion of
one molecule of ethene into the growing chain) amounts to some 105s
only(Table 6). A comparison with enzymes is not far-fetched.As
shown by Tait under these conditions every zirconium atom forms an
activecomplex and produces about 20 000 polymer chains per hour. At
temperatures above50
C, the zirconium catalyst is more active than the hafnium or
titanium system; the latteris decomposed by such temperatures.
Transition metal compounds containing somehalogene show a higher
activity than systems that are totally free of halogen. Of
thecocatalysts, methylalumoxane is much more eective than the
ethylaluminoxane orisobutylalumoxane.It is generally assumed that
the function of MAO is rstly to undergo a fast ligandexchange
reaction with the metallocene dichloride, thus rendering the
metallocene methylTable 5 Ethene polymerizationawith
metallocene/methylaluminoxane catalysts.MetallocenebStructure
Activity[kg PE/(mol Zr.h.cmon]Molecular weight(g/mol)Cp2ZrCl2 6 60
900 62 000[Me2C(Ind)(Cp)]ZrCl2 8 3330 18 000[En(IndH4)2]ZrCl2 9 22
200 1 000 000[Em(Ind)2]ZrCl2 11 12 000 350 000[En(Ind)2]HfCl2 12
2900 480 000[Me2Si(Ind)2]ZrCl2 13 36 900 260
000[Me2Si(2,4,7-Me3Ind)2]ZrCl2 15 111 900 250
000[Me2C(Flu)(Cp)]ZrCl2 18 2000 500 000aEthene pressure 2.5 bar.
temp. 30
C. [metallocene] 6.25 106M. Metaliocene/MAO250. Solvent toluene;
bCp cyclopentadienyl; Indindenyl; EnC2H4; Fluuorenyl.Copyright 2005
by Marcel Dekker. All Rights Reserved.and dimethyl compounds
(Figure 3). In the further step, either Cl or CH3 is abstractedfrom
the metallocene compound by al Al-center in MAO, thus forming a
metallocenecation and a MAO anion [156,157]. The alkylated
metallocene cation represents the activecenter (Figure 4).
Meanwhile, other weakly coordinating cocatalysts, such
astetra(peruorophenyl)borate anions [(C6F5)4B], have been
successfully applied to theactivation of metallocenes
[158161].Polyethenes synthesized by metallocene-alumoxane have a
molecular weight dis-tribution of Mw/Mn2, 0.9 to 1.2 methyl groups
per 1000 C atoms, 0.11 to 0.18 vinylgroups, and 0.02 trans vinyl
group per 100 C atoms. The molecular weight can easily belowered by
increasing the temperature, increasing the metallocene
concentration, orFigure 2 Some classes of metallocene catalysts
used for olefin polymerization.Copyright 2005 by Marcel Dekker. All
Rights Reserved.Table 6 Polymerization activity of
bis(cyclopentadienyl)zirconium dichloride/methylalumoxane catalyst
applied to ethene in 330 ml of toluene.Activity (95
C), 8 bar 39.8 106g PE/g Zr h[Zirconocene] 6.2
108mol/l[Alumoxane] (M1200) 7.1 104mol/lMolecular weight of the
polyethene obtained 78 000Degree of polymerization
2800Macromolecules per Zr atom per hour 46 000Rate of growth of one
macromolecule 0.087 sTurnover time 3.1 105sFigure 3 Reactions of
zirconocenes with MAO.Copyright 2005 by Marcel Dekker. All Rights
Reserved.decreasing the ethene concentration. The molecular weight
distribution can be decreasedup to 1.1 (living polymerization) by
bis(phenoxy-imine)titanium complexes [161].Molecular weights of 170
000 were obtained. The molecular weight is also lowered bythe
addition of small amounts) (0.1 to 2 mol%) of hydrogen (e.g.,
without H2,Mw170 000; adding 0.5 mol% H2, Mw42 000) [155].7. Late
Transition Metal CatalystBrookhart et al. [57,58] described square
planar nickel and palladium-diimine systemswhich are capable of
polymerizing ethene to high molecular weight polymers with
activ-ities comparable to the metallocene catalyst systems when
activated with methyl-aluminoxane.25 26Important for the
polymerization activity is the substituent 1 which has to be a
bulkyaryl group. The task of this substituent is to ll up the
coordination spheres below andabove the square plane of the complex
and thus enable the growing polymer chain to staycoordinated to the
metal center. This is one of the main dierences to the
well-knownSHOP catalysts invented by Keim et al. [164] and
Ostoja-Starzewski and Witte [165] whichproduces mainly ethene
oligomers.Figure 4 Mechanism of the polymerization of olefins by
zirconocenes. Step 1: The cocatalyst(MAO: methylalumoxane) converst
the catalyst after complexation into the active species that has
afree coordination position for the monomer and stabilizes the
latter. Step 2: The monomer (alkene) isallocated to the complex.
Step 3: Insertion of the alkene into the zirconium alkyl bond and
provisionof a new free coordination position. Step 4: Repetition of
Step 3 in a very short period of time (about2000 propene molecules
per catalyst molecule per second), thus rendering a polymer
chain.Copyright 2005 by Marcel Dekker. All Rights Reserved.27The
use bis(ylid)nickel catalysts by reaction of nickel oxygen
complexes andphosphines [166].For the one-component catalyst, it is
possible to use solvents of various polarities.Even in THF or
acetone there is good activity. The best solvents are methylene
chlorideor hexane. If the hydrogen next to the oxygen in the ylid
is replaced by larger groups,the activity increases and reaches at
10-bar ethene pressure and 100
C about 50 000 mol ofreacted ethene per mole of nickel [167].A
very interesting feature of this new catalyst generation is that
chain isomerizationprocesses can take place during the
polymerization cycles. This results in more or lessbranched
polymers with varying product properties depending on
polymerizationconditions and catalyst type. The number of
isomerization cycles which are carried outdirectly one after
another determines the nature of the branching formed.
Branchesranging from methyl to hexyl and longer can be formed.The
extent of branching can be tailored precisely by tuning the
polymerizationconditions and products, from highly crystalline HDPE
to completely amorphous poly-mers with glass transition
temperatures of about 50
C. These products are dierent toall known conventionally
produced copolymers due to their content and distributionpattern of
short chain branching [168].Another new catalyst generation based
on iron and cobalt. The direct iron analogsof the nickel-diimine
catalysts derived from structures (25) and (26) did not seem to
bevery active in olen polymerization at all. The electronic and
steric structure analysisshows why: the nickel d8-system favors a
square planar coordination sphere but theiron d6-system favors a
tetrahedral one. It is very likely that these tetrahedral
coordinationsites are not available for olen insertion, and hence
no polymerization can take place.The next logical step was the
employment of another electron donating atom inthe ligand structure
in order to obtain a trigonal-bipyramidal coordination
sphere.Gibson and Brookhart both succeeded with a catalyst system
based on an ironbisiminopyridyl complex. The structures (28)(30)
illustrate the three types of catalysts[169,170].28Square
planarCopyright 2005 by Marcel Dekker. All Rights
Reserved.29Tetrahedral30Trigonal-bipyramidalThe ethene
polymerization activity of these new family of catalysts is
comparablewith the one obtained with the most productive
metallocenes under similar conditionsif activated with
methylaluminoxane. Again, the nature of the aryl substituents R1
plays amajor role in controlling the molecular weight of the
polymers.In contrast to nickel-diimine catalysts no chain
isomerization takes place and thusonly linear HDPE is formed.In
1998, Grubbs [171,172] reported on a new type of neutral
nickelII-complexes withsalicylaldimin ligands (structure (31)).
With these catalysts low branched polyethyleneswere obtained with a
narrow molecular weight distribution. The copolymerization ofethene
and norbornene is possible.31C. Copolymers of EtheneThe properties
of polyethene could be varied in a wide range by copolymerization
ofethene with other comonomers. Most commercial products contain at
least small amountsof other monomers. In general, adding comonomers
to the polymerization reduces thepolyethenes crystallinity, thereby
reducing the melting point, the freezing point, and inmany cases
the tensile strength and modulus. At the same time, optical
properties areCopyright 2005 by Marcel Dekker. All Rights
Reserved.improved and polarity is increased. The architecture of
the copolymer can be controlledexperimentally by the following
factors: operating conditions, chemical composition andphysical
state of used catalyst, physical state of the copolymer being
formed, and structureof the comonomers.The practically most
important copolymer is made from ethene and propene.Titanium- and
vanadium-based catalysts have been used to synthesize copolymers
thathave a prevailingly random, block, or alternating structure.
Only with Ziegler or singlesite catalyst, longer-chain a-olens can
be used as comonomer (e.g., propene, 1-butene,1-hexene, 1-octene).
In contrast to this, by radical high-pressure polymerization it is
alsopossible to incorporate functional monomers (e.g., carbon
monoxide, vinyl acetate). Thepolymerization could be carried out in
solution, slurry, or gas phase. It is generally accepted[173] that
the best way to compare monomer reactivities in a particular
polymerizationreaction is by comparison of their reactivity ratios
in copolymerization reactions.The simplest kinetic scheme of binary
copolymerization in the case of olen insertionreaction
isCatM1polymer M1 !k11CatM1M1polymer 32CatM1polymer M2
!k12CatM2M1polymer 33CatM2polymer M1 !k21CatM1M2polymer
34CatM2polymer M2 !k22CatM2M2polymer 35r1 k11k12r2 k22k2136where
k11 and k22 are the homopolymerization propagation rates for
monomers M1 and M2and k12 and k21 are cross-polymerization rate
constants. The denition of reactivity ratios isdM1
dM2
M1r1M1 M2
M2M1 r2M2
37The product r1r2 usually ranges from zero to 1. When r1r21,
the copoly-merization is random. As r1r2 approaches zero, there is
an increasing tendency towardalternation.1. Radical
CopolymerizationAt elevated temperatures, ethene can be
copolymerized with a number of unsaturatedcompounds by radical
polymerization [174180] (Table 7). The commercially mostimportant
comonomers are vinyl acetate [181], acrylic acid, and methacrylic
acid as well astheir esters. Next to these carbon monoxide is
employed as a comonomer, as it promotesthe polymers degradability
in the presence of light [182].As a consequence of the diversied
nature of the comonomers, a large number ofvariants of copolymer
composition can be realized, thus achieving a broad variation
ofproperties. The copolymerization can be carried out in the liquid
monomer, in a solvent,or in aqueous emulsion. When high molecular
mass is desired, solvents with low chaintransfer constants (e.g.,
tert-butanol, benzene, 1,4-dioxane) are preferred.
SolutionCopyright 2005 by Marcel Dekker. All Rights
Reserved.polymerization permits the use of low polymerization
temperatures and pressures.Poly(ethylene-co-vinyl acetate, for
instance, is produced at 100
C and 14 to 40 MPa [183].For the polymerization of ethene with
vinyl acetate and vinyl chloride, emulsionpolymerization in water
is particularly suitable. The polymerizates have gained
someimportance as adhesives, binding materials for pigments, and
coating materials [184,185].2. Linear Low-Density Polyethene
(LLDPE)In contrast to LDPE produced with the high-pressure process,
the tensile strength inLLDPE is much higher. Therefore, there has
been a considerable boost in the productionof LLDPE [186]. All
Ziegler catalysts listed earlier are suitable for the
copolymerization ofethene with other monomers. Monomers that
decrease the melting point and crystallinityof a polymer at low
concentrations are of great interest. Portions of 2 to 5 mol%
areused. Longer-chained monomers such as 1-hexene are more eective
at the same weightconcentration than smaller units such as propene.
It results in a branched polyethene withmethyl branching (R) if
propene is used, ethyl if butene is used, and so on.38Important for
the copolymerization are the dierent ractivities of the olens.
Theprincipal order of monomer reactivities is well known [187];
ethene > propene >1-butene >linear a-olens > branched
a-olens. Normally propene reacts 5 to 100 times slower thanethene,
and 1-butene 3 to 10 times slower than propene. Table 8 shows the
reactivity ratiosfor the copolymerization of ethene with other
olens. The data imply that the reactivity ofthe polymerization
center is not constant for a given transition metal compound
butdepends on the structure of the innermost monomer unit of the
growing polymer chainand on the cocatalyst.On a laboratory scale,
single site catalysts based on metallocene/MAO are highlyuseful for
the copolymerization of ethene with other olens. Propene, 1-butene,
1-pentene,1-hexene, and 1-octene have been studied in their use as
comonomers, forming linear low-density polyethene (LLDPE)
[188,189]. These copolymers have a great industrial potentialand
show a higher growth rate than the homopolymer. Due to thee short
branching fromTable 7 Copolymerization of ethene (M1) with various
comonomers (M2).Comonomer r1 r2 Pressure (MPa) Temp. (
C)Propene 3.2 0.62 102170 1202201-Butene 3.2 0.64 102170
130220Isobutylene 2.1 0.49 102170 130220Styrene 0.7 1 150250
100280Vinyl acetate 1 1 110190 200240Vinyl chloride 0.16 1.85 30
70Acrylic acid 0.09 196204 140226Acrylic acid methylester 0.12 13
82 150Acrylnitrile 0.018 4 265 150Methacrylic acid 0.1 204
160200Methacrylic acid methylester 0.2 17 82 150Copyright 2005 by
Marcel Dekker. All Rights Reserved.the incorporated a-olen, the
copolymers show lower melting points, lower crystallinities,and
lower densities, making lms formed from these materials more exible
and betterprocessible. Applications of the copolymers can be found
in packaging, in shrink lmswith a low steam permeation, in elastic
lms, which incorporate a high comonomerconcentration, in cable
coatings in the medical eld because of the low part of
extractables,and in foams, elastic bers, adhesives, etc. The main
part of the comonomers is randomlydistributed over the polymer
chain. The amount of extractables is much lower than inpolymers
synthesized with Ziegler catalysts.The copolymerization parameter
r1, which says how much faster an ethene unit isincorporated into
the growing polymer chain than an a-olen, if the last inserted
monomerwas an ethene unit, lies between 1 and 60 depending on the
kind of comonomerand catalyst. The product r1 r2 is important for
the distribution of the comonomer andis close to one when using
C2-symmetric catalysts [190] (Table 9).Under the same conditions,
syndiospecic (Cs-symmetric) metallocenes are moreeective in
inserting a-olens into an ethene copolymer than isospecic
working(C2-symmetric) metallocenes or unbridged metallocenes. In
this particular case,hafnocenes are more ecient than zirconocenes,
too.An interesting eect is observed for the polymerization with
ethylene(bisindenyl)-zirconium dichloride and some other
metallocenes. Although the activity of the homo-polymerization of
ethene is very high, it increases when copolymerizing with propene
[191].The copolymerization of ethene with other olens is eected by
the variation ofthe Al/Zr ratio, temperature and catalyst
concentration. These variations change themolecular weight and the
ethene content. Higher temperatures increase the ethene contentand
lower the molecular weight.Table 8 Reactivity ratios of ethene with
various comonomers and heterogeneous TiCl3 catalystby 70
C.Comonomer Cocatalyst r1 r2 Ref.Propene Al(C6H13)3 15.7 0.11
174Propene AlEt3 9.0 0.10 1741-Butene AlEt3 60 0.025
1784-Methyl-1-pentene AlEt2Cl 195 0.0025 177Styrene AlEt3 81 0.012
179Table 9 Results of ethene reactivity ratio determinations with
soluble catalystsa.Metallocene Temp. (
C) a-Olen r1 r2 r1 r2Cp2ZrMe2 20 Propene 31 0.005
0.25[En(Ind)2]ZrCl2 50 Propene 6.61 0.06 0.40[En(Ind)2]ZrCl2 25
Propene 1.3 0.20 0.26Cp2ZrCl2 40 Butene 55 0.017 0.93Cp2ZrCl2 60
Butene 65 0.013 0.85Cp2ZrCl2 80 Butene 85 0.010 0.85[En(Ind)2]ZrCl2
30 Butene 8.5 0.07 0.59[En(Ind)2]ZrCl2 50 Butene 23.6 0.03
0.71Cp2ZrMe2 60 Hexene 69 0.02 1.38[Me2Si(Ind)2]ZrCl2 60 Hexene 25
0.016 0.40Copyright 2005 by Marcel Dekker. All Rights
Reserved.Studies of ethene copolymerization with 1-butene using the
Cp2ZrCl2/MAO catalystindicated a decrease in the rate of
polymerization with increasing comonomer concen-tration.3.
Ethene-Propene CopolymersThe copolymers of ethene and propene, with
a molar ratio of 1:0.5 up to 1:2, are of greatindustrial interest.
These EP-polymers show elastic properties and, together with 25
wt%of dienes as third monomers, they are used as elastomers (EPDM).
Since there areno double bonds in the backbone of the polymer, it
is less sensitive to oxidation reaction.Ethylidenenorbornene,
1,4-hexadiene and dicyclopentadiene are used as dienes. In
mosttechnical processes for the production of EP and EPDM rubber,
soluble or highly disposedvanadium components have been used in the
past (Table 10) [192195]. Similar elastomerswhich are less coloured
can be obtained with metallocene/MAO catalyst at a muchhigher
activity [196]. The regiospecicity of the metallocene catalysts
towards propeneleads exclusively to the formation of head-to-tail
enchainments. Ethylidenenorbornenepolymerizes via vinyl
polymerization of the cyclic double bond and the tendency
ofbranching is low. The molecular weight distribution of about 2 is
narrow [197].At low temperatures the polymerization time to form
one polymer chain is longenough to consume one monomer and then to
add another one. So, it becomes possibleto synthesize block
copolymers if the polymerization, catalyzed especially by
hafnocenes,starts with propene and, after the propene is nearly
consumed, continues with ethene.High branching, which is caused by
the incorporation of long chain olens into thegrowing polymer
chain, is obtained with silyl bridged
amidocyclopentadienyltitaniumcompounds (structure (39))
[198200].39Table 10 Results of ethene reactivity ratio
determinations with soluble catalystsa.Catalyst Cocatalyst Temp.
(
C) r1(Ml) r2(M2) r1 r2 Ref.VCl4 AlEt2Cl 21 3.0 0.073 0.23
192VCl4 Al-i-Bu2Cl 20.0 0.023 0.46 193VOCl3 Al-i-Bu2Cl 30 16.8
0.052 0.87 192V(acac)3 Al-i-Bu2Cl 20 16.0 0.04 0.64 193VOCl2(OEt)
Al-i-Bu2Cl 30 16.8 0.055 0.93 194VOCl2 Al-i-Bu2Cl 30 18.9 0.069
1.06 194VO(OBu)3 Al-i-Bu2Cl 30 22.0 0.046 1.01 194VO(OEt)3
Al-i-Bu2Cl 30 15.0 0.070 1.04 194VO(OEt)3 AlEt2Cl 30 26.0 0.039
1.02 195aMonomer 1 ethene, monomer 2 propene.Copyright 2005 by
Marcel Dekker. All Rights Reserved.These catalysts, in combination
with MAO or borates, incorporate oligomers withvinyl endgroups
which are formed during polymerization by b-hydrogen transfer
resultingin long chain abranched polyolens. In contrast,
structurally linear polymers are obtainedwhen catalysed by other
metallocenes. Copolymers of ethylene with 1-octene are veryexible
materials as long as the comonomer content is less than 10%.With
higher 1-octene content they show that elastic properties polyolen
elastomers(POE) are formed [201]. EPDM is a commercially important
synthetic rubber. The dienesas terpolymers are curable with sulfur.
This rubber shows a higher growth rate than theother synthetic
rubbers [202]. The outstanding property of ethene-propene rubber is
itsweather resistance since it has no double bonds in the backbone
of the polymer chain andthus is less sensitive to oxygen and ozone.
Other excellent properties of this rubber are itsresistance to
acids and alkalis, its electrical properties, and its
low-temperatureperformance [203].EPDM rubber is used in the
automotive industry for gaskets, wipers, bumpers,and belts. In the
tire industry, EPM and EPDM play a role as a blending
component,especially for sidewalls. Furthermore, EPDM is used for
cable insulation and inthe housing industry, for roong as well as
for many other purposes, replacing specialrubbers [204].For
technical uses, the molecular weight (Mw) is in the range 100 000
to 200 000.EPDM rubber, synthesized with vanadium catalyst, show a
molecular weight distributionbetween 3 and 10, indicating that two
and more active centers are present.The properties of the
copolymers depend to a great extent on several structuralfeatures
of the copolymer chains as the relative content of comonomer units,
the way thecomonomer units are distributed in the chain, the
molecular weight and molecular weightdistribution, and the relative
content of normal head-to-tail addition or
head-to-head/tail-to-tail addition.4. Ethene-Cycloolefin
CopolymersMetallocene/methylaluminoxane (MAO) catalysts can be used
to polymerize and copoly-merize strained cyclic olens such as
cyclobutene, cyclopentene, norbornene, DMON andother sterically
hindered olens [205210]. While polymerization of cyclic olens
byZieglerNatta catalysts is accompanied by ring opening [10],
homogeneous metallocene[211], nickel [212,213], or palladium
[214,215], catalysts achieve exclusive double bondopening
polymerization.40 41 42Copolymerization of these cyclic olens with
ethylene or a-olens cycloolencopolymers (COC) can be produced,
representing a new class of thermoplastic amorphousmaterials
[217220]. Early attempts to produce such copolymers were made
usingheterogeneous TiCl4/VAlEt2Cl or vanadium catalysts, but rst
signicant progress wasCopyright 2005 by Marcel Dekker. All Rights
Reserved.made by utilizing metallocene catalysts for this purpose.
They are about ten times moreactive than vanadium systems and by
careful choice of the metallocene, the comonomerdistribution may be
varied over a wide range by selection of the appropriate
cycloolenand its degree of incorporation into the polymer chain.
Statistical copolymers becomeamorphous at comonomer incorporations
beyond 1015 mol% cycloolen.COCs are characterized by excellent
transparency and very high, long-life servicetemperatures. They are
soluble, chemically resistant and can be melt-processed. Due
totheir high carbon/hydrogen ratio, these polymers feature a high
refractive index, e.g. 1.53for ethene-norbornene copolymer at 50
mol% norbornene incorporation. Their stabilityagainst hydrolysis
and chemical degradation, in combination with their stiness lets
thembecome desirable materials for optical applications, e.g. for
compact disks, lenses, opticalbers and lms. The rst commercial COC
plant run by Ticona GmbH with a capacityof 30 000 tons a year
commerced production in September 2000 and is located inOberhausen,
Germany.The rst metallocene-based COC material was synthesized from
ethene and cyclo-pentene [218]. While homopolymerization of
cyclopentene results in 1,3-enchainment ofthe monomer units [219],
isolated cyclopentene units are incorporated into the
ethene-cyclopentene copolymer chain by 1,2-insertion. Ethylene is
able to compensate the sterichindrance at the a-carbon of the
growing chain after and before the insertion ofcyclopentene
[220].Ethene-norbornene copolymers are most interesting for
technical applicationsas they can be made from easily available
monomers and provide glass transitiontemperatures up to 200
C. Table l1 presents the activities and comonomer ratios for
theseveral applied catalysts of C2- and Cs-symmetry. Cs-symmetric
zirconocenes are moreactive in the copolymerization than for the
homopolymerization of ethene. Under thechosen conditions,
[En(Ind)2]ZrCl2 develops the highest activity while the
highestcomonomer incorporation is achieved by
[Ph2C(Ind)(Cp)]ZrCl2.Due to dierent incorporation ratios of the
cyclic olen into the copolymer, the glasstransition temperature can
vary over a wide range which is basically independent of theapplied
catalyst. A copolymer containing 50 mol% of norbornene yields a
material witha glass transition point of 145
C. Considering COCs of dierent comonomers with equalcomonomer
ratios, increased Tg values can be observed for the bulkier
comonomer, forinstance 72
C for ethene-norbornene and 105
C for ethene-DMON at comonomer moleratio XCo0.30 each.The
copolymerization parameters r1 and r2 were calculated from the
rates of incor-poration, determined by 13C NMR spectroscopy,
dependent on the reaction temperature.Table 12 shows the
temperature dependence of the copolymerization parametersrl and r2
and of the inuence of the catalyst systems. Metallocene catalysts
show low r1values, which increases with the temperature and allows
the easy incorporation of bulkycycloolens into the growing polymer
chain. Surprisingly, the copolymerization parameterr11.83.1 for
cyclopentene and norbornene is surprisingly low. The r1 value of 2
meansthat ethylene is inserted only twice as fast as norbornene.The
product r1 r2 shows whether statistical insertion (r1 r2) or
alternating one(r1 r20) has occurred. The dierent catalysts produce
copolymers with structures thatare between statistical and
alternating.Due to dierent incorporation values of the cyclic olen
in the copolymer, the glasstransition temperature can vary over a
wide range that is independent of most of the usedcatalysts (Figure
5). Acopolymer with 50 mol% of norbornene yields a material with a
glasstransition point of 145
C. A Tg of 205
C can be reached by higher incorporation rates.Copyright 2005 by
Marcel Dekker. All Rights Reserved.The Tg values are raised with a
bulkier cycloolen, regarding the same incorporationrate of 30%
(norbornene: Tg72
C; DMON: Tg105
C). The highest glass transitiontemperature with 229
C was reached by a copolymer of ethene and
5-phenylnorbornene.Copolymerization of ethene and norbornene with
[Me2C(Flu)(tert-BuCp)]ZrCl2leads to a strong alternating structure
[221]. This copolymer is crystalline and shows amelting point of
295
C, good heat resistance and resistance against unpolar
solvents.5. Ethene-Copolymerization by Styrene or Polar MonomersThe
copolymerization of ethene and styrene is possible by single site
catalysts such asmetallocenes and amido (see structure (33))
[222,223]. Amounts of more than 50 mol%of styrene could be
incorporated into the copolymer. In dependence of the
styrenecontent the copolymers show elastic to sti properties. The
polymerization happens byboth 1,2- and 2,1-insertion of the styrene
unit; the regioselectivity is low.While it is dicult to
copolymerize ethene and polar monomers by Ziegler- or single-site
catalysts because of the great reactivity of the active sites to
polar groups, it iscommercialized to use free radical
polymerization by high ethene pressure.Vinyl acetate and acrylate
esters used as comonomers containing sucient stabilizerto prevent
the homopolymerization. The eect of the copolymerization with
polarTable 11 Copolymerization of norbornene (N) and ethene (E) by
different metallocene/MAOcatalysts at 30
C. Conditions: MAO/Zr 200, c(Zr) 5 106mol/l; p(E) 2.00 bar,c(N)
0.05 mol/l.Catalyst t [min] Activity[kg/mol h]Incorp. of
norbornene[weight %]Cp2ZrCl2 30 1200 21.4[En(Ind)2]ZrCl2 10 9120
26.1[Me2Si(Ind)2]ZrCl2 15 2320 28.4[En(IndH4)2]ZrCl2 40 480
28.1[Me2C(Flu)(Cp)]ZrCl2 10 7200 28.9[Ph2C(Flu)(Cp)]ZrCl2 10 6000
27.3[Ph2C(Ind)(Cp)]ZrCl2 15 2950 33.3Table 12 Copolymerization
parameters r1 and r2 of ethene/cycloolefin copolymerization
withdifferent metallocene/MAO catalysts.Cycloolen Catalyst Temp. in
C r1 r2 r1 r2Cyclopentene [En(IndH4)2]ZrCl2 0 1.9 350
C), and resistance to strong oxidizing agents
[601].Chlorouoroethylene is homo- and copolymerized by
free-radical-initiated polymerizationin bulk [602], suspension, or
aqueous emulsion using organic and water-soluble
initiators[603,604] or ionizing radiation [605], and in solution
[606]. For bulk polymerization,trichloroacetyl peroxide [607] and
other uorochloro peroxides [608,609] have been usedas initiators.
Redox initiator systems are described for the aqueous
suspensionpolymerization [603,604]. The emulsion polymerization
needs uorocarbon and chloro-uorocarbon emulsiers [610].Oils and
waxes with excellent chemical inertness are obtained from
low-molar-masspoly(chlorotriuoroethylene). They are prepared by
polymerization of the monomer in thepresence of suitable chain
transfer agents [601]. Furthermore, chlorotriuoroethylene hasbeen
copolymerized with vinylidene uoride to elastomeric polymers by
suspension andemulsion polymerization [601,611].Most of the other
uorine-containing monomers such as
triuoroethylene,hexauoropropylene, and pentauoropropylene are used
only for copolymerization withvinyl uoride, vinylidene uoride, and
tetrauoroethylene [506,521,535,559562]. Thosecopolymers, after a
convenient vulcanization procedure using peroxides, diisocyanates,
oramines, can be applied as uorocarbon elastomers [564]. Due to the
uorine content, theyhave high chemical resistance and often a broad
temperature range for application [612].Polymers of interest are
the vinylideneuoride/hexauoropropylene copolymer and theCopyright
2005 by Marcel Dekker. All Rights Reserved.vinylidene
uoride/hexauoro-propylene-tetrauoroethylene terpolymer. Also, a
copoly-mer of vinylidene uoride and 1-hydropentauoro-propylene
[612] or peruoro(methylvinyl ether) [613,614] is commercially
available as elastomer. The co- or terpolymerizationcan be carried
out in aqueous phase with an inorganic water-soluble persulfate as
theinitiator [611] and under conditions similar to those used for
TFE and VF2 alone [598].Other uorocarbon polymers result from the
copolymerization of vinylidene uoridewith uorine-containing
acrylates [e.g., F2C=CHCOOR, F2C=CFCOOCH3,F2C=C(CF3)COF] and are
mentioned mainly in the patent literature [615]. Aninteresting
thermoplastic uoropolymer from Allied Chemical Corp., called CM-1,
isreported [616]. This copolymer from hexauoroisobutylene and
vinylidene uoride can beradically polymerized in suspension or
emulsion at a pressure of 10 to 20 bar and atemperature of 20
C. The properties of the copolymer are comparable or even better
thanthose of poly (tetrauoroethylene).VI. POLY(TETRAFLUOROETHENE)
(PTFE)(This section was prepared by O. Nuyken and R. Jordan.)A.
IntroductionPoly(tetrauoroethene) (PTFE) was serendipitously
discovered by Roy Plunkett atDuPonts Jackson Laboratory [617] in
1938, while attempting to prepare uorocarbonderivatives. He
described the formation of an inert, white, opaque solid by
storing(polymerizing) tetrauoroethene (TFE) in a cylinder. Soon the
unique properties of PTFEwere discovered and various methods of the
polymerization of TFE followed. PTFE ismainly manufactured by
free-radical polymerization methods of TFE in aqueous
media.Suitable initiators [618] include ammonium, sodium, and
potassium persulfate, hydrogenperoxide, oxygen, and some organic
peroxy compounds. Redox systems involvingpersulfate with either
ferrous ion or bisulte or the use of bisulte with ferric ion are
usefulcombinations [619]. Photo-initiated, radiation-initiated,
glow-discharge and plasmapolymerization are also applied.PTFE with
an estimated ultrahigh molar mass of >107g/mol is in many
respects aunique polymer due to its insolubility in any common
solvent, chemical inertness e
