Temperature Equilibration Rate with Fermi-Dirac Statistics

TL;DR

This paper presents a systematic, first-principles calculation of electron-ion temperature equilibration rates in plasmas using Fermi-Dirac statistics and a novel application of dimensional continuation, providing accurate results for weakly to moderately coupled plasmas.

Contribution

It introduces a systematic perturbative method employing dimensional continuation to calculate temperature equilibration rates, including error estimates, for quantum plasmas.

Findings

Degeneracy corrections are comparable to quantum corrections below Born approximation.

The method yields nearly exact results for weakly to moderately coupled plasmas.

Calculation becomes unreliable for strongly coupled plasmas.

Abstract

We calculate the electron-ion temperature equilibration rate in a fully ionized, weakly to moderately coupled plasma, using an exact treatment of the Fermi-Dirac electrons. The temperature is sufficiently high so that the quantum-mechanical Born approximation to the scattering is valid. At the heart of this calculation lies the method of dimensional continuation, a technique that we borrow from quantum field theory and use in a novel fashion to regulate the kinetic equations in a consistent manner. We can then perform a systematic perturbation expansion and thereby obtain a finite first-principles result to leading and next-to-leading order. Unlike model building, this systematic calculation yields an estimate of its own error and thus prescribes its domain of applicability. The calculational error is small for a weakly to moderately coupled plasma, for which our result is nearly exact. It should also be emphasized that our calculation becomes unreliable for a strongly coupled plasma, where the perturbative expansion that we employ breaks down, and one must then utilize model building and computer simulations. Besides providing new and potentially useful results, we use this calculation as an opportunity to explain the method of dimensional continuation in a pedagogical fashion. Interestingly, in the regime of relevance for many inertial confinement fusion experiments, the degeneracy corrections are comparable in size to the subleading quantum correction below the Born approximation. For consistency, we therefore present this subleading quantum-to-classical transition correction in addition to the degeneracy correction.