Calculation of the expansion in a graphite crystal by Cn interstitials

This investigation has been lead in two complementary ways: An E.S.R. study at very low temperatures of linewidth and g-factor anisotropies on two kinds of pyrographites (P.G.). The influence on these physical quantities of the neutron irradiation, in order to check the validity of a previously expo

A simple model of the effect of interstitial atoms on the interlayer properties of a graphite crystal is derived and compared with experimental data. The analysis yields the derivatives of the interaction energy of an interstitial and the adjacent layers. Itis concluded that interstitial cat-bon ato

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

A calculation is presented of the elastic constant CM of a graphite crystal as a function of temperature up to 2500 K, taking into account the anharmonic contribution and the changes in interlayer interactions due to the large lattice thermal expansion. Parametric variations in the theory show that

Calculations are made of Cs3, &, 8Cs~/&zzt and the A-A stacking fault energy of a graphite crystal using Lennard-Jones potentials between atoms in different layer planes. An estimate is made of aC,,/ae,,. The values of Cs3 and the A-A stacking fault energy are in fair agreement with experiment, but