Litcius/Paper detail

Examining the high-pressure response and shock melting in cerium using optical pyrometry

B. J. Jensen, Thomas Hartsfield, D. B. Holtkamp, F. J. Cherne, R. Corrow, Thomas Graves, A. J. Iverson

2020Physical review. B./Physical review. B31 citationsDOI

Abstract

The ability to measure temperature in shock wave experiments has been a long-standing scientific challenge complicated by the short timescales involved ($<1$ microsecond) and the presence of nonthermal or external light sources that pollute measured radiances using optical pyrometry methods. In the current work, we present the first experimental data on cerium metal designed to measure the temperature on-Hugoniot from the low-pressure $\ensuremath{\alpha}$ phase well into the high-pressure liquid phase. Radiance data obtained in this work were used to determine the Hugoniot curves for solid ($\ensuremath{\alpha}$-Ce) and liquid cerium by measuring the longitudinal stress and temperature simultaneously in the shocked state. These data were used to estimate the temperature for incipient shock melting and complete melting, and to further constrain a multiphase equation of state developed to describe the dynamic response of cerium at high pressures.

Topics & Concepts

PyrometerCeriumMicrosecondMaterials scienceShock waveRadianceShock (circulatory)Phase (matter)Work (physics)Explosive materialEquation of stateThermodynamicsMeasure (data warehouse)Temperature measurementOpticsPhysicsChemistryMetallurgyMedicineDatabaseInternal medicineComputer scienceQuantum mechanicsOrganic chemistryHigh-pressure geophysics and materialsEnergetic Materials and CombustionSolid-state spectroscopy and crystallography