Phonon instabilities in uniaxially compressed fcc metals as seen in molecular dynamics simulations

G. KIMMINAU; P. ERHART; E.M. BRINGA; B.A. REMINGTON; J.S. WARK

PHYSICAL REVIEW B

AMER PHYSICAL SOC

Año: 2010 vol. 81 p. 92102 - 92106

1098-0121

We show that the generation of stacking faults in perfect face-centered-cubic (fcc) crystals, uniaxially compressed along [001], is due to transverse-acoustic phonon instabilities. The position in reciprocal space where the instability first manifests itself is not a point of high symmetry in the Brillouin zone. This model provides a useful explanation for the magnitude of the elastic limit, in addition to the affects of box size, temperature, and compression on the time scale for the generation of stacking faults. We observe this phenomenon in both simulations that use the Lennard-Jones potential and embedded atom potentials. Not only does this work provide fundamental insight into the microscopic response of the material but it also describes certain behavior seen in previous molecular dynamics simulations of single-crystal fcc metals shock compressed along the principal axis.