Prime, Michael B., Arsenlis, Athanasios, Austin, Ryan A., Barton, Nathan R., Battaile, Corbett C., Brown, Justin L., Burakovsky, Leonid, Buttler, William T., Chen, Shuh-Rong, Dattelbaum, Dana M., Fensin, Saryu J., Flicker, Dawn G., Gray III, George T., Greeff, Carl, Jones, David R., Lane, J. Matthew D, Lim, Hojun, Luscher, D.J., Mattsson, Thomas R., and McNaney, James M.
[Display omitted] By combining experiments and modeling from three US national laboratories, we explore compressive strength in a well-characterized material, tantalum, across pressures from zero to over 350 GPa, strain-rates from 10 − 3 /s to 10 8 /s and temperatures from 148 K to 3800 K. Strength values from 40+ experiments are shown to vary by nearly two orders of magnitude, from 0.15 GPa to over 10 GPa. Cross-comparison of these results allows pressure and strain-rate dependencies to be isolated, and strength increases more significantly with pressure than with strain rate over the range studied. Simulations using Preston-Tonks-Wallace, Livermore Multi-Scale, and Kink-Pair strength models test modeling capabilities and provide further insight into strength mechanics. The widely-used assumption in those models of shear-modulus scaling underpredicts strength by a factor of about two at extreme pressures in pulsed-power planar ramp-release experiments, which largely isolate pressure effects. Richtmyer-Meshkov Instability experiments, which largely isolate strain rate effects at ∼ 10 7 /s, suggest that modeling assumptions about mechanisms at the highest rates need further study. Laser-driven Rayleigh-Taylor instability experiments, which simultaneously probe extreme pressures and strain rates, provide both model and cross-platform experimental validation. The large-scale collaborative nature of this study covers a wide span of experimental conditions and modeling approaches, allowing for extraordinary insight into dynamic strength. [ABSTRACT FROM AUTHOR]