Tandem Molecular Dynamics and Continuum Studies of Shock‐Induced Pore Collapse in TATB

Zhao, Puhan; Lee, Sangyup; Sewell, Tommy; Udaykumar, H. S.

doi:10.1002/prep.201900382

Cited by 55 publications

(66 citation statements)

References 84 publications

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“…The relative strength of the pressuretemperature functional dependencies of the RDX melt curve and shear viscosity are similar in magnitude to recent determinations for HMX [24] and TATB [21]. Thus, it can be expected that grain scale simulation predictions of hot spot formation and growth in RDX will exhibit similar sensitivity as was found for those explosives [28,29,24]. Both the melt curve and shear viscosity were shown to independently alter peak hot spot temperatures by hundreds of Kelvin in HMX and TATB, which provides strong motivation for including the present results in future grain scale models of RDX.…”

Section: Discussionsupporting

confidence: 82%

“…In the case of HMX (octahydro-1,3,5,7tetranitro-1,3,5,7-tetrazocine), estimates of the melt curve based on the Lindemann law [32] were shown to be substantially lower than predictions obtained from MD simulations at GPa-range pressures [24]. Application of MD-derived melt curves for HMX [24] and TATB (1,3,5-triamino-2,4,6-trinitrobenzene) [21] in grain scale simulations of supported shocks were shown to effectively suppress melting during the collapse of micron-and sub-micron scale pores [24,28,29].…”

Section: Introductionmentioning

confidence: 92%

“…[a] M. P. Kroonblawd length and time scales has recently been used to calibrate and validate grain scale model terms through direct comparison [25][26][27][28][29][30][31]. Despite the promise of a one-and-done approach to calibration through scalebridging simulations, it is often more advantageous to gradually increase grain scale model complexity and independently determine physics terms due to the highly coupled and nonlinear nature of dynamic material response [24,28,29]. This is especially true for material parameters that vary significantly within the applicable temperature and pressure domain such as the melt curve and liquid shear viscosity [15,21,24].…”

Section: Introductionmentioning

confidence: 99%

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Predicted Melt Curve and Liquid Shear Viscosity of RDX up to 30 GPa

Kroonblawd

Springer

2021

Preprint

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Recent grain scale simulations of HMX and TATB have shown that predictions for hot spot formation in high explosives are particularly sensitive to accurate determinations of the pressure-dependent melt curve and the shear viscosity of the liquid phase. These physics terms are poorly constrained beyond ambient pressure for the explosive RDX. We adopt an all-atom modeling approach using molecular dynamics (MD) simulations to predict the melt curve of RDX near to detonation conditions (30 GPa) and determine the shear viscosity of the liquid as a function of temperature and pressure above the melt curve. Phase-coexistence simulations were used to determine the melt curve, which is predicted to vary by almost 1100 K as the pressure increases from 0 GPa to 30 GPa. Equilibrium MD simulations and the Green-Kubo formalism were used to obtain the pressure-temperature dependent shear viscosity. The shear viscosity of RDX is predicted to be of similar magnitude to the viscosity of TATB at low GPa-range pressures, and to be roughly an order of magnitude lower than the viscosity of HMX. The temperature dependence of the shear viscosity is Arrhenius at a given pressure, and the exponential pre-factor and activation term exhibit a strong, yet complicated, pressure dependence. An empirical pressure-temperature dependent function for RDX shear viscosity is developed that simultaneously captures a wide range of MD predictions while taking an analytic form that extrapolates smoothly beyond the fitted regime. The relative strength of the pressure and temperature dependencies of these two physics terms is found to be of similar magnitude for RDX, HMX, and TATB, which motivates incorporating these results in future RDX grain scale modeling.

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Section: Discussionsupporting

confidence: 82%

Section: Introductionmentioning

confidence: 92%

Section: Introductionmentioning

confidence: 99%

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Predicted Melt Curve and Liquid Shear Viscosity of RDX up to 30 GPa

Kroonblawd

Springer

2021

Preprint

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“…A study of shock-induced pore collapse in TATB using both continuum and MD simulations was reported by Zhao et al 15 A quasi-2D simulation cell containing a cylindrical pore in the MD simulations (for three different crystal orientations) and a 2D cell containing a circular pore in the continuum treatment were studied at three impact speeds chosen to span collapse mechanisms ranging from predominantly visco-plastic to hydrodynamic. The MD simulations used an all-atom non-reactive force field (the same one used here) and the continuum calculations were performed using a baseline isotropic, elastic-perfectly plastic strength model.…”

Section: Introductionmentioning

confidence: 99%

Strongly Anisotropic Thermomechanical Response to Shock Wave Loading in Oriented Samples of the Triclinic Molecular Crystal 1,3,5-Triamino-2,4,6-Trinitrobenzene (TATB)

Zhao

Kroonblawd²,

Mathew³

et al. 2021

Preprint

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All-atom molecular dynamics simulations were used to study shock wave loading in oriented single crystals of the highly anisotropic triclinic molecular crystal 1,3,5-triamino-2,4,6-trinitrobenzene (TATB). The crystal structure consists of planar hydrogen-bonded sheets of individually planar TATB molecules that stack into graphitic-like layers. Shocks were studied for seven systematically prepared crystal orientations with limiting cases that correspond to shock propagation exactly perpendicular and exactly parallel to the graphitic-like layers. The simulations were performed for initially defect-free crystals using a reverse-ballistic configuration that generates explicit, supported shocks. Final longitudinal stress components are between »8.5 GPa and »10.5 GPa for the 1.0 km s<sup>-1</sup> impact speed studied. Orientation-dependent properties are reported including shock speeds, stresses, temperatures, compression ratios, and local material strain rates. Spatio-temporal maps of the temperature, stress tensor, material flow, and molecular orientations reveal complicated processes that arise for specific shock directions. The results indicate that TATB shock response is highly sensitive to crystal orientation, with significant qualitative differences for the time evolution of the stress tensor and temperature, elastic/inelastic compression response, defect formation and growth, critical von Mises stress, and strain rates during shock rise that span nearly an order of magnitude. A variety of inelastic deformation mechanisms are identified, ranging from crumpling of graphitic-like layers to dislocation-mediated plasticity to intense shear strain localization. To our knowledge, these are the first systematic MD simulations and analysis of explicit shock wave propagation along non-trivial crystal directions in a triclinic molecular crystal.

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“…Alternatively, note that other works have relied on very short-range repulsion corrections to circumvent the high pressure limitation of the original EXP6 potential. [22,42] It will be specified explicitly which flavor of the potential was used in each section of this paper. Note that the OPLS-AA potential is non-reactive and therefore can describe only chemically inert processes: however, Mattsson et al [18] estimated numerically that reactions begin to take place above 15 GPa for polybutadiene which is around the highest pressures obtained in our simulations.…”

Section: Potentialsmentioning

confidence: 99%

Hugoniostat and Direct Shock Simulations in cis‐1,4‐Polybutadiene Melts

Lecoutre

Lemarchand

Soulard

et al. 2020

Macro Theory & Simulations

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The non‐reactive OPLS‐AA force‐field is used to compare direct shock and Hugoniostat simulations of a melt of cis‐1,4‐polybutadiene at different shock velocities and with chain lengths up to 500 monomers. Both methods yield equivalent Hugoniot data with negligible influence of the chain length. However, it is found that the dynamical compression effects induce a time‐dependent anisotropy in the stress tensor in the direct shock simulations, yielding a non‐zero shear component. This anisotropy vanishes to the usual isotropic stress through two specific relaxation mechanisms: a fast process (characteristic time ≈1 ps) associated with the relaxation of the local intramolecular degrees of freedom of the chains, and a second slower process (characteristic time ≈100 ps) associated with the structural reorganisation of the polymer chains, involving long‐range intramolecular and intermolecular interactions. A third potential relaxation process, associated with entanglements, may be at play but is beyond the scope of the present study.

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Tandem Molecular Dynamics and Continuum Studies of Shock‐Induced Pore Collapse in TATB

Cited by 55 publications

References 84 publications

Predicted Melt Curve and Liquid Shear Viscosity of RDX up to 30 GPa

Predicted Melt Curve and Liquid Shear Viscosity of RDX up to 30 GPa

Strongly Anisotropic Thermomechanical Response to Shock Wave Loading in Oriented Samples of the Triclinic Molecular Crystal 1,3,5-Triamino-2,4,6-Trinitrobenzene (TATB)

Hugoniostat and Direct Shock Simulations in cis‐1,4‐Polybutadiene Melts

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