# Sloshing of Galaxy Cluster Core Plasma in the Presence of   Self-Interacting Dark Matter

**Authors:** John ZuHone (CfA), Jes\'us Zavala (U. of Iceland), Mark Vogelsberger, (MIT)

arXiv: 1901.11140 · 2019-09-25

## TL;DR

This study uses simulations to explore how increasing dark matter self-interactions affect gas sloshing and cold front formation in galaxy clusters, revealing impacts on gas dynamics, turbulence, and potential observational constraints.

## Contribution

It demonstrates how dark matter self-interactions modify cluster core dynamics and cold front development, providing new insights into dark matter properties through gas behavior analysis.

## Key findings

- Higher DM self-interaction cross sections slow sloshing gas movement.
- Self-interactions lead to flattened DM cores and reduced turbulence.
- Separation of X-ray and Sunyaev-Zeldovich peaks constrains DM self-interactions.

## Abstract

The "sloshing" of the cold gas in the cores of relaxed clusters of galaxies is a widespread phenomenon, evidenced by the presence of spiral-shaped "cold fronts" in X-ray observations of these systems. In simulations, these flows of cold gas readily form by interactions of the cluster core with small subclusters, due to a separation of the cold gas from the dark matter (DM), due to their markedly different collisionalities. In this work, we use numerical simulations to investigate the effects of increasing the DM collisionality on sloshing cold fronts in a cool-core cluster. For clusters in isolation, the formation of a flat DM core via self-interactions results in modest adiabatic expansion and cooling of the core gas. In merger simulations, cold fronts form in the same manner as in previous simulations, but the flattened potential in the core region enables the gas to expand to larger radii in the initial stages. Upon infall, the subcluster's DM mass decreases via collisions, reducing its influence on the core. Thus, the sloshing gas moves slower, inhibiting the growth of fluid instabilities relative to simulations where the DM cross section is zero. This also inhibits turbulent mixing and the increase in entropy that would otherwise result. For values of the cross section $\sigma/m > 1$, subclusters do not survive as self-gravitating structures for more than two core passages. Additionally, separations between the peaks in the X-ray emissivity and thermal Sunyaev-Zeldovich effect signals during sloshing may place constraints on DM self-interactions.

## Full text

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## Figures

17 figures with captions in the complete paper: https://tomesphere.com/paper/1901.11140/full.md

## References

92 references — full list in the complete paper: https://tomesphere.com/paper/1901.11140/full.md

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Source: https://tomesphere.com/paper/1901.11140