Derivation of the Kompaneets equation using the boost operator approach

TL;DR

This paper introduces a boost operator method to derive the Kompaneets equation and its extensions, providing a transparent and general framework for radiative transfer and scattering problems involving photons and electrons.

Contribution

The work presents a novel, generalizable boost operator approach to derive the Kompaneets equation and its higher order corrections, simplifying calculations in radiative transfer.

Findings

Derived the Kompaneets equation using the boost operator approach.

Reproduced known anisotropic and higher order temperature correction expressions.

Provided new expressions for boost operators in general directions.

Abstract

The repeated scattering of photons by thermal electrons at low temperatures is described by the Kompaneets equation and its generalized forms that include anisotropies and higher order temperature corrections. In this work, we use the boost operator approach to derive the related expressions in a transparent way that showcases the generality of the formalism and its application to radiative transfer problems. We consider the simplest form of the Kompaneets equation for the scattering in isotropic media at the leading order in the electron temperature and then include anisotropies in the photon field, reproducing previously obtained expressions for the evolution equations. For this we use expressions for the scattering operator in the electron rest frame up to first order in the electron recoil, O(h nu/m_e c^2), but then work at all orders in the electron momentum, p, as easily obtained with the boost operator approach. This shows how specific transformation rules can be formulated that allow simplification of the otherwise cumbersome and repetitive calculations. We also confirm the expressions for higher order temperature corrections in isotropic media, highlighting the validity of the approach presented here. As part of the derivation, we find expressions for the boost operator in general boost directions which we believe will also be useful in other applications of the formalism.