Continuum and molecular dynamics simulations of pore collapse in shocked beta-tetramethylene tetranitramine (beta-HMX) single crystals
CA Duarte and CY Li and BW Hamilton and A Strachan and M Koslowski, JOURNAL OF APPLIED PHYSICS, 129, 015904 (2021).
DOI: 10.1063/5.0025050
The collapse of pores plays an essential role in the shock initiation of high energy (HE) materials. When these materials are subjected to shock loading, energy is localized in hot-spots due to various mechanisms, including void collapse. Depending on the void size and shock strength, the resulting hot-spots may quench or evolve into a self-sustained deflagration wave that consequently can cause detonation. We compare finite element (FE) and non-reactive molecular dynamic (MD) simulations to study the formation of hot-spots during the collapse of an 80nm size void in a beta -tetramethylene tetranitramine energetic crystal. The crystal is shocked normal to the crystallographic plane ( 010 ), applying boundary velocities of 0.5km/s, 1.0km/s, and 2.0km/s. The FE simulations capture the transition from viscoelastic collapse for relatively weak shocks to a hydrodynamic regime, the overall temperature distributions, especially at scales relevant for the initiation of HE materials, and the rate of pore collapse. A detailed comparison of velocity and temperature fields shows that the MD simulations exhibit more localization of plastic deformation, which results in higher temperature spikes but localized to small volumes. The void collapse rate and temperature field are strongly dependent on the plasticity model in the FE results, and we quantify these effects.
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