Stellar-like Galactic center excess challenges particle dark matter

TL;DR

This study reevaluates the Galactic Center as a target for dark matter detection, using advanced gamma-ray analysis to distinguish between dark matter signals and stellar sources, setting new limits on dark matter properties.

Contribution

It introduces a combined template fitting and pixel-count statistical approach to better separate dark matter signals from stellar sources in gamma-ray data.

Findings

Stringent upper limits on dark matter annihilation cross section for masses below 300 GeV.

Supports stellar population explanation for the Galactic Center Excess over dark matter.

Results are robust against simulated data tests.

Abstract

The Galactic Center (GC) is potentially hosting the largest indirect signal from particle dark matter (DM), which in many well-motivated models would produce gamma rays as their final states. However, this region has often been dismissed for DM studies because of the evidence for an unexpected gamma-ray component over astrophysical backgrounds at GeV energies, firstly discovered in the data of the \textit{Fermi} Large Area Telescope (LAT), the so-called Galactic Center Excess (GCE). While this was initially considered to hint at GeV thermal relics, recent work supports a GCE interpretation in terms of a stellar population of millisecond pulsar-like sources in the Galactic bulge. Building on this preference, we re-evaluate the GC as a powerful target for indirect DM searches via gamma rays. This is achieved by combining adaptive template fitting and pixel-count statistical methods to assess the role of sub-threshold point sources in the observed \textit{Fermi}-LAT gamma-ray counts, while minimizing the mismodeling of Galactic diffuse emission backgrounds. In a fully self-consistent way, the gamma-ray data are fitted with a mixed model comprising a DM signal and a stellar bulge, both potentially contributing to the GCE. The space left for signals from weak-scale DM particle annihilations is quantified by extracting 95\% C.L. upper limits on the annihilation cross section, which, depending on the DM density profile, result in stringent limits for masses $\lesssim 300$ GeV. The robustness of our results is supported by tests on simulated data.