High- and low-entropy layers in solids behind shock and ramp compression waves

TL;DR

This paper investigates the formation of high- and low-entropy temperature layers near interfaces in metals under shock and ramp loading, supported by theoretical, computational, and molecular dynamics analyses.

Contribution

It introduces a detailed analysis of entropy layer formation in shock and ramp loading, highlighting the importance of these layers in simulations of surface and interface effects.

Findings

High-entropy layers form at impact and shock interfaces.

Low-entropy layers can develop during ramp loading.

Molecular dynamics support continuum model predictions.

Abstract

Non-uniform temperature fields are analyzed, which arise in the problems of formation of the steady shock wave at impact and ramp loading of metals, exit of the steady shock wave to the free surface, and the shock wave passing through the interface between two different materials. Theoretical analysis and computations show that high-entropy (with the temperature increase) and low-entropy (with the temperature decrease) layers arise near the interfaces in the above problems of shock and ramp loading. The impact produces the high-entropy layer; while the ramp loading can result in the both high- and low-entropy layers. At the shock wave passing through the interface, the high-entropy layer is formed in the lower-impedance material and the low-entropy -- in the higher-impedance one. The formation of high-entropy layer at impact is supported by molecular-dynamics simulations in addition to continuum modeling. The high- and low-entropy layers should be taken into account in simulations of shock-wave processes in thin targets or in other cases where surface effects are important.