Molecular dynamics study of diffusionless phase transformations in HMX: β-HMX twinning and β-ε phase transition

Abstract

We use molecular dynamics to study mechanism of deformation twinning of β-1,3,5,7-tetranitro-1,3,5,7-tetrazocane (β-HMX) in the P21/n space group setting for the twin system specified by K1=(101), η1=[101], K2=(101), and η2=[101] at T=1 K and 300 K. Twinning of a single perfect crystal was induced by imposing increasing stress. The following three forms of stress were considered: uniaxial compression along [001], shear stress in K1 plane along η1 direction, and shear stress in K2 plane along η2 direction. In all cases the crystal transforms to its twin by the same mechanism: as the stress increases, the a and c lattice parameters become, respectively, longer and shorter; soon after the magnitude of a exceeds that of c the system undergoes a quick phase-transition-like transformation. This transformation can be approximately separated into two stages: glide of the essentially intact \101\ crystal planes along 101 crystal directions followed by rotations of all HMX molecules accompanied by N-NO2 and CH2 group rearrangements. The overall process corresponds to a military transformation. If uniaxial compression along [001] is applied to a β-HMX crystal which is already subject to a hydrostatic pressure 10 GPa, the transformation described above proceeds through the crystal-plane gliding stage but only minor molecular rearrangements occurs. This results in a high-pressure phase of HMX which belongs to the P21/n space group. The coexistence curve for this high-pressure phase and β-HMX is constructed using the harmonic approximation for the crystal Hamiltonians.