Constraining Extended Gamma-ray Emission from Galaxy Clusters

TL;DR

This study searches for gamma-ray emission from galaxy clusters to detect dark matter annihilation signals, but finds no significant extended emission, instead setting upper limits that constrain dark matter models and cosmic ray contributions.

Contribution

The paper provides new upper limits on gamma-ray emission from galaxy clusters, accounting for unresolved sources and systematic uncertainties, improving constraints on dark matter annihilation.

Findings

No significant extended gamma-ray emission detected.

Upper limits on dark matter annihilation cross section are more stringent than dwarf galaxy analyses.

Fornax and Virgo limits align with theoretical models, Coma limit is below expectations.

Abstract

Cold dark matter models predict the existence of a large number of substructures within dark matter halos. If the cold dark matter consists of weakly interacting massive particles, their annihilation within these substructures could lead to diffuse GeV emission that would dominate over the annihilation signal of the host halo. In this work we search for GeV emission from three nearby galaxy clusters: Coma, Virgo and Fornax. We first remove known extragalactic and galactic diffuse gamma-ray backgrounds and point sources from the Fermi 2-year catalog and find a significant residual diffuse emission in all three clusters. We then investigate whether this emission is due to (i) unresolved point sources; (ii) dark matter annihilation; or (iii) cosmic rays (CR). Using 45 months of Fermi-LAT data we detect several new point sources (not present in the Fermi 2-year point source catalogue) which contaminate the signal previously analyzed by Han et al.(arxiv:1201.1003). Including these and accounting for the effects of undetected point sources, we find no significant detection of extended emission from the three clusters studied. Instead, we determine upper limits on emission due to dark matter annihilation and cosmic rays. For Fornax and Virgo the limits on CR emission are consistent with theoretical models, but for Coma the upper limit is a factor of 2 below the theoretical expectation. Allowing for systematic uncertainties associated with the treatment of CR, the upper limits on the cross section for dark matter annihilation from our clusters are more stringent than those from analyses of dwarf galaxies in the Milky Way. We rule out the thermal cross section for supersymmetric dark matter particles for masses as large as 100 GeV (depending on the annihilation channel).