NEEP 541 - PowerPoint PPT Presentation

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NEEP 541

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Vacancies form loops or collapse lattice within layer planes. Growth occurs perpendicular to layer planes due to interstitials and shrinkage ... – PowerPoint PPT presentation

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Title: NEEP 541


1
NEEP 541 Graphite Damage
  • Fall 2002
  • Jake Blanchard

2
Outline
  • Radiation Damage in Graphite
  • Graphite structure
  • Swelling
  • Thermomechanical properties
  • sputtering

3
Graphite Crystal Structure
  • Crystal is hexagonal
  • Planes of atoms are strongly bonded (covalent)
    within the plane, but the plane-to-plane bonding
    is relatively weak (van der Waals) lubrication
  • Crystal cleaves easily parallel to the basal
    planes
  • Physical properties are highly anisotropic

4
Different Views of Structure
5
Phase Diagram
6
Types of Graphite
  • Pyrolitic highly oriented
  • Polycrystalline graphites with randomly oriented
    grains
  • POCO graphite is fine-grained, giving it high
    strength and high failure strains
  • Graphnol is similar to POCO, but with smaller
    thermal expansion coefficient

7
Irradiation of Graphite
  • Neutron irradiation produces point defects
  • Interstitials form loops (immobile) or small,
    mobile clusters
  • Vacancies form loops or collapse lattice within
    layer planes
  • Growth occurs perpendicular to layer planes due
    to interstitials and shrinkage occurs parallel to
    planes due to relaxation of lattice around
    vacancies or lines of vacancies

8
Swelling of Graphite
  • Graphite usually shrinks initially due to pore
    closure
  • Graphite is porous due to cooling from the
    graphitizing temperature
  • After initial shrinkage, growth occurs
  • When volume returns to initial value, structural
    properties are poor

9
Polycrystalline Graphite35 dpa 600-690 C
10
Pyrolitic Graphite
11
Pyrolytic Graphite
12
Isotropic Graphite
13
Thermomechanical Properties
  • Modulus and thermal conductivity increase as
    density increases, then decrease

14
Polycrystalline Graphite
Thermal expansion coefficient
Thermal conductivity
Elastic modulus
15
Pyrolitic GraphiteParallel to Planes
16
Pyrolitic GraphitePerpendicular to Planes
17
Sputtering
  • Both physical and chemical sputtering occur in
    graphite

18
Pyrolitic Carbon Sputtering
He
D
H
19
Chemical Sputtering
  • Molecules are formed on surface due to chemical
    reaction between incident ion and carbon atoms
    with binding energy low enough to desorb
  • Molecule then is not bound to surface
  • A third process (radiation enhanced sublimation)
    allows target atoms to be thermally released from
    surface

20
Chemical Sputtering
  • With incident hydrogen, sputtering yield peaks
    around 800-900 K
  • Peak yield is 0.1 ions/ion

21
Chemical Sputtering1 keVProtons
22
Methane Production - Protons
23
Methane Yield 2 keV protons
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