156. Interstitial atom energies in graphite

A theoretical analysis of the free interstitial in graphite has been made using various atomic interaction potential functions with a view to reconciling experimental and theoretical values for the interstitial formation and basal-plane migration energies. Earlier calculations of Coulson et al.[l l]

The energy required to displace a carbon atom from its normal lattice site has been determined directly by detection of the lattice vacancies resulting from the displacement process. Annealed natural crystals of graphite containing less than 10-i' vacancies per carbon atom were irradiated at room te

initiation and propagation mechanisms under tensile 45045 Orleans, France). No long or short abstract loading. These results were used in developing an submitted. analytical model for tensile failure based on microstructural parameters and micromechanical principles. 61. Structural evolution of a gl

The energy required to displace a carbon atom from its normal lattice site has been determined directly by detection of the lattice vacancies resulting from the displacement process. Annealed natural crystals of graphite containing less than 10-i' vacancies per carbon atom were irradiated at room te

The model used to evaluate the single interstitial migration energy from property changes due to interstitials is extended to account for vacancy contributions. The annealing function obtained can be used to determine the relative contributions of the defects and is sufficiently sensitive to disting