Detecting dark matter sub-halos in the Galactic plane with the Cherenkov Telescope Array Observatory

TL;DR

This study evaluates the Cherenkov Telescope Array Observatory's potential to detect dark matter sub-halos in the Galactic plane, focusing on detection prospects, modeling tidal effects, and estimating required annihilation cross sections for observability.

Contribution

It provides the first detailed assessment of CTAO's capability to detect dark matter sub-halos in the Galactic plane, considering tidal effects and survey specifics.

Findings

Detection at 5σ level possible for cross section ~3×10⁻²⁵ cm³/s for individual sub-halos.

Detection of the brightest sub-halos requires cross sections ~10⁻²³ to 10⁻²² cm³/s.

Regions a few degrees above or below the Galactic plane are most promising for detection.

Abstract

Numerous observations confirm the existence of dark matter (DM) at astrophysical and cosmological scales. Theory and simulations of galaxy formation predict that DM should cluster on small scales in bound structures called sub-halos or DM clumps. While the most massive DM sub-halos host baryonic matter, less massive, unpopulated sub-halos could be abundant in the Milky Way (MW), as well and yield high-energy gamma rays as final products of DM annihilation. Recently, it has been highlighted that the brightest halos should also have a sizeable extension in the sky. In this study, we examine the prospects offered by the Cherenkov Telescope Array Observatory (CTAO), a next-generation gamma-ray instrument, for detecting and characterizing such objects. Previous studies have primarily focused on high-latitude observations; here, we assess the potential impact of the CTAO's Galactic Plane Survey, which will provide unprecedentedly deep survey data for the inner five degrees of the Galactic plane. Our modeling accounts for tidal effects on the sub-halo population, examining the conditions under which DM sub-halos can be detected and distinguished from conventional astrophysical sources. We find that regions a few degrees above or below the Galactic plane offer the highest likelihood for DM sub-halo detection. For an individual sub-halo -- the brightest from among various realizations of the MW subhalo population -- we find that detection at the 5$\sigma$ level is achievable for an annihilation cross section of $\langle \sigma v \rangle \sim 3\times10^{-25}$ cm$^3$/s for TeV-scale DM annihilating into $b\bar{b}$. For a full population study, depending on the distribution and luminosity model of Galactic sub-halos, yet unconstrained cross sections in the range $\langle \sigma v \rangle \sim 10^{-23}-10^{-22}$ cm$^3$/s for TeV DM candidates are necessary for the brightest sub-halos to be detected.