Empirical test for relativistic kinetic theories based on the Sunyaev-Zel'dovich effect

TL;DR

This paper introduces a method to determine the electron velocity distribution in galaxy cluster gas using the Sunyaev-Zel'dovich effect, enabling tests of relativistic kinetic theories through high-precision measurements.

Contribution

It presents a novel approach combining simulations and SZ data analysis to distinguish between different relativistic electron velocity distributions in galaxy clusters.

Findings

A 1% SZ measurement error can differentiate EV distributions with high significance.

Simulations show the method can distinguish Juttner and modified Juttner distributions in merging clusters.

The approach can test fundamental relativistic kinetic theories using observational data.

Abstract

We propose a new method to determine the electron velocity (EV) distribution function in the intracluster gas (ICG) in clusters of galaxies based on the frequency dependence of the Sunyaev-Zel'dovich (SZ) effect. It is generally accepted that the relativistic equilibrium EV distribution is the one suggested by Juttner. However, there is an ongoing debate on the foundation of relativistic kinetic theory, and other distributions have also been proposed. The mildly relativistic intracluster gas (ICG) provides a unique laboratory to test relativistic kinetic theories. We carried out Monte Carlo simulations to generate SZ signal from a single-temperature gas assuming the Juttner EV distribution assuming a few per cent errors. We fitted SZ models based on non-relativistic Maxwellian, and its two relativistic generalizations, the Juttner and modified Juttner distributions. We found that a 1% error in the SZ signal is sufficient to distinguish between these distributions with high significance based on their different best-fit temperatures. However, in any LOS in a cluster, the ICG contains a range of temperatures. Using our N-body/hydrodynamical simulation of a merging galaxy cluster and assuming a 1% error in the SZ measurements in a LOS through a bow shock, we find that it is possible to distinguish between Juttner and modified Juttner distributions with high significance. Our results suggest that deriving ICG temperatures from fitting to SZ data assuming different EV distribution functions and comparing them to the temperature in the same cluster obtained using other observations would enable us to distinguish between the different distributions.11 pages, 8 figures, and 1 table, accepted for publication in the Astrophysical Journal