Irradiation Effects in Graphite – from the Nano- to the Mille-Metric Scale
Tim Burchell
Distinguished R & D Staff Member
Fusion Materials & Nuclear Structures Group
Materials Science & Technology Division
INGSM-15HANGZHOU, CHINASept 15-18, 2015
2 Managed by UT-Battellefor the U.S. Department of Energy
AcknowledgementsMany colleagues at ORNL and INL, and
coworkers in the field of radiation damage and nuclear graphite
This work is sponsored by the
U.S. Department of Energy, Office of Nuclear Energy Science and Technology under contract DE-AC05-00OR22725 with Oak Ridge National
Laboratory, managed by UT-Battelle, LLC.
Use of the High Flux Isotope Reactor at the Oak Ridge National Laboratory was supported by the
U.S Department of Energy.
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OUTLINE
Role of Graphite in Nuclear Reactors
Mechanism of Irradiation Damage
Effects of Irradiation Damage
Irradiation Creep
Summary and Conclusions
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Role of Graphite in a Nuclear Reactor
• Neutron moderator
– Thermalize fast neutrons to sufficiently low energies that they can efficiently fission 92U235
• Neutron reflector – returns neutrons to the active core
• Graphite (nuclear grade) has a low neutron capture cross section
• High temperature material
• Used in numerous operating reactors (Magnox, AGRs, RBMKs, and HTRs such as HTTR and HTR-10)
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Role of Graphite in a Nuclear Reactor (continued)
• Graphite is the reactor core structural material
• HTGR cores are constructed from graphite blocks
• In prismatic cores the graphite fuel elements retain the nuclear fuel
• In a pebble bed the graphite reflector structure retains the fuel pebbles
• The graphite reflector structure contains vertical penetrations for reactivity control
• Reactivity control channels are also contained in prismatic graphite fuel elements
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The GT-MHR Utilizes Ceramic Coated Particle Fuel
The TRISO fuel particles are formed into 12 mm diameter graphite (carbon) fuel sticks and are inserted into graphite fuel blocks
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Graphite Core Components – Pebble Type HTGR (PBMR)
•NBG-18 Graphite blocks form the PBMR outer reflector
•Reflector penetrations are for the control rods and reserve shutdown system
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The Pebble Type HTGR Utilizes Ceramic Coated Particle Fuel
The TRISO fuel particles are combined into a graphite (carbon) fuel ball (pebble)6 cm in diameter
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NBG-18 Graphite Microstructure
• New nuclear grade
• SGL Carbon
• Vibrationally molded
• Pitch coke filler (1.6 mm max size)
• Pore structure characterized using Optical microscopy & automatic Image analysis
• X-ray tomography
• Hg-intrusion
Multiple length scales: nm crystals, µm to mm particles; nm to mm pores
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Fine Grain Nuclear Graphite (IG-110)
High Temperature Test Reactor (Japan), Fuel Blocks and Replaceable Reflector Blocks
HTR-10 & HTR-DM, Permanent Core Structure
•Fine grain (~20 μm)
•High CTE 4-5 x 10-6 0C-1
•High strength
• isotropic properties and irradiation response
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OUTLINE
Role of Graphite in Nuclear Reactors
Mechanism of Irradiation Damage
Effects of Irradiation Damage
Irradiation Creep
Summary and Conclusions
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Neutron Irradiation Damage
•Neutron irradiation causes carbon atom displacement•Dimensional and physical property changes result•Damage mechanism well understood•Key physical properties are:
irradiation dimensional stability, strength, elastic moduli, thermal expansion coefficient, thermal conductivity, radiation creep behavior, fracture behavior, oxidation behavior
GRAPHITE CRYSTALSTRUCTURE
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The Radiation Damage Mechanism In Graphite
CARBON ATOM BINDING ENERGY IN GRAPHITE LATTICE IS 7 eV
DISPLACEMENT ENERGY FOR CARBON ATOM IS APPROX. 30 eV
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Low Temperature Stored Energy Release
Burchell T, Carbon Materials for Advanced Technologies, Chpt. 13 (1999) p. 429
(Adapted from Nightingale, Nuclear Graphite (1962) )
•Tirr ~ 30oC
•Hanford K
•Reactor test
•Data
•Traditionally associated with Frenkel pair recombination
•New evidence?
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Displacement Damage in Layered Graphitic Structures
• Sequential high resolution transmission electron microscope images illustrating the formation rates of interlayer defects at different temperatures with the same electron irradiation flux & time scale (0 to 220 seconds). (a) 93K, (b) 300K, (c) 573K, in double-wall carbon nanotubes.
• The arrows indicate possible interlayer defects.Urita, K.; Suenaga, K.; Sugai, T.;
Shinohara, H.; Iijima, S. Physical Review Letters 2005, 94, 155502.
2 nm
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Displacement Damage in Layered Graphitic Structures
• Normalized formation rate of the clusters of I-V pair defects per unit area of bilayer estimated in HRTEM images recorded at different temperatures
• The dotted line shows the known temperature for Wigner-energy release (~473 K)
• Heggie & Telling, University of Sussex, UK: Simulations of spiro-interstitial
Urita, K.; Suenaga, K.; Sugai, T.; Shinohara, H.; Iijima, S. Physical Review Letters 2005, 94, 155502.
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Radiation Damage In Graphite Is Temperature Dependent
INTERSTITIALSMobile at room temperature.Above ~200oC form into clusters of 2 to 4 interstitials.Above 300oC form new basal planes which continue to grow at temperatures up to 1400oC.
VACANCIESImmobile below 300oC. 300-400oC formation of clusters of 2-4 vacancies which diffuse in the basal planes and can be annihilated at crystallite boundaries (function of lattice strain and crystal perfection).Above 650oC formation of vacancy loops.Above 900oC loops induce collapsing vacancy lines.
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Basal Planes in Layered Graphitic Structures
A high-resolution electron micrograph showing the basal planes of a graphitic nano-particle with an interstitial loop between two basal planes, the ends of the inserted plane are indicated with arrows.
Banhart, F. Rep. Prog. Phys. 1999, 62, 1181–1221.
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OUTLINE
Role of Graphite in Nuclear Reactors
Mechanism of Irradiation Damage
Effects of Irradiation Damage
Irradiation Creep
Summary and Conclusions
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Neutron Irradiation Induced Dimensional Change
• Graphite dimensional changes are a result of crystallite dimensional change and graphite texture.
• Swelling in c-direction is initially accommodated by aligned microcracks that form on cooling during manufacture.
• Therefore, the a-axis shrinkage initially dominates and the bulk graphite exhibits net volume shrinkage.
• With further irradiation, incompatibilities in crystallite strains causes the generation of new porosity and the volume shrinkage rate falls eventually reaching zero.
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Neutron Irradiation Induced Dimensional Change (continued)
• The graphite begins to swell at an increasing rate with increasing
damage dose due to c-axis growth and new pore generation.
• The graphite thus exhibits volume “turnaround” behavior from initial
shrinkage to growth.
• Eventually loss of mechanical integrity occurs due to excessive
pore/crack generation.
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Radiation Induced Volume Changesin H-451 (Effect of Temperature)
Interplaner cracks and porosity accommodate thermal expansion and c-axis irradiation induced swelling
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Radiation Induced Dimensional Changes in H-451 (Effect of Texture)
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Neutron Irradiation Induced Changes in Young’s Modulus
•Initial rise due to dislocation pinning
•Subsequent increase due to volume shrinkage (densification)
•Eventual turnover and reduction due to pore/crack generation and volume expansion
• (σ0)E/E0)1/2
H-451 Graphite
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Thermal Conductivity ChangesUmklapp and Defect Scattering
IG-110 samples from HTK-7 (Tirr=600oC)
0
20
40
60
80
100
120
140
160
0 200 400 600 800 1000 1200
Temperature, oC
Th
erm
al
Co
nd
ucti
vit
y,
W.m
/K
12.1 dpa
24.8 dpa
25.8 dpa
Unirradiated
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OUTLINE
Role of Graphite in Nuclear Reactors
Mechanism of Irradiation Damage
Effects of Irradiation Damage
Irradiation Creep
Summary and Conclusions
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Radiation Damage in Nuclear Graphite –inelastic deformation
Irradiation Induced Creep in Graphite
-4.0
-3.5
-3.0
-2.5
-2.0
-1.5
-1.0
-0.5
0.0
0 5 10 15 20 25 30
Fast Neutron Fluence / dpa
Rel
. Lin
. Dim
ensi
onal
Cha
nges
(%)
-3.5
-3.0
-2.5
-2.0
-1.5
-1.0
-0.5
0.0
0.5
1.0
1.5
0 5 10 15 20 25 30
Fast Neutron Fluence / dpa
Rel
. Lin
. Dim
ensi
onal
Cha
nges
(%)
ATR-2E Graphite (WG), Tirr = 550°C, 5 MPa compressive stress
ATR-2E Graphite (WG), Tirr = 500°C, 5 MPa tensile stress
Graphite dimensional change behavior is modified by the application of stress. Tensile stress hastens turnaround and compressive stress delays turnaround
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A Comparison of Compressive and Tensile Creep Strain Behavior for ATR-2E Graphite
G. Haag. Report No. Jul-4183, FZ-J GermanyIrradiation Temperature =500-550oC
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OUTLINE
Role of Graphite in Nuclear Reactors
Mechanism of Irradiation Damage
Effects of Irradiation Damage
Irradiation Creep
Summary and Conclusions
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Summary and Conclusions• > 60 years experience with graphite as a solid moderator• Physics of irradiation damage well understood, but some areas still require a more satisfactory explanation:
•Exact nature of irradiation induced defect structures at elevated temperatures•Roles of basal plane and prismatic edge dislocations in the deformation processes•Possible contribution of other dislocation mechanisms (such as dislocation climb/glide) in the creep deformation mechanism.•Interaction of crystal strain with porosity/cracks and the ultimate creation of new porosity & cracks
• The application of advanced analytical techniques (HRTEM, SANS) combined with further experimentation (irradiation creep capsules) may provide the explanation we seek• Knowledge and models are required across multi length scales linking the atomic structure to the crystal structure, through the microstructure to the component (nano to macro) and the reactor core behavior.
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Knowledge and multiscale models linking to describe complex materials behavior from
the sub-nanoscale to the millimetric (component) scale
Electronic structure, MD simulations
Meso-scale models, diffusion models
Micro-mechanical models
Finite Element models and large scale simulations
nm m mm m
ATOMIC STRUCTURE
CRYSTAL STRUCTURE
MICROSTRUCTURE
COMPONENTS & STRUCTURES