Thermodynamics of the insulator-metal transition in dense liquid deuterium

Abstract

Recent dynamic compression experiments [M. D. Knudson, Science 348, 1455 (2015)10.1126/science.aaa7471; P. M. Celliers, Science 361, 677 (2018)10.1126/science.aat0970] have observed the insulator-metal transition in dense liquid deuterium, but with an approximately 95-GPa difference in the quoted pressures for the transition at comparable estimated temperatures. It was claimed in the latter of these two papers that a very large latent heat effect on the temperature was overlooked in the first, requiring correction of those temperatures downward by a factor of 2, thereby putting both experiments on the same theoretical phase boundary and reconciling the pressure discrepancy. We have performed extensive path-integral molecular dynamics calculations with density functional theory to directly calculate the isentropic temperature drop due to latent heat in the insulator-metal transition for dense liquid deuterium and show that this large temperature drop is not consistent with the underlying thermodynamics.