Temperature dependent determination of electron heat capacity and electron-phonon factor for Fe0.72Cr0.18Ni0.1

Abstract

A theoretical approach using ab initio calculations has been applied to study the interaction of an ultra-short laser pulse with the metal alloy Fe0.72Cr0.18Ni0.1 (AISI 304). The electronic structure is simulated by taking into account the chemical and magnetic disorder of the alloy by the coherent potential approximation implemented in a fully relativistic Korringa-Kohn-Rostoker-formalism in the framework of spin density functional theory. Utilizing these predictions we determined the electron heat capacity and the electron-phonon coupling factor of Fe0.72Cr0.18Ni0.1 in dependence on the electron temperature for two-temperature model applications. Compared with pure Fe a maximum deviation of 5~\% for the electron heat capacity and 25~\% for the electron-phonon coupling factor is found.