Leo I: the classical dwarf spheroidal galaxy with the highest dark-matter density

TL;DR

This study reveals Leo I as the classical dwarf spheroidal galaxy with the highest dark matter density, providing new insights into its dark matter profile and implications for dark matter detection strategies.

Contribution

Building on recent dynamical models, we precisely characterize Leo I's dark matter density and profile, highlighting its significance in dark matter research and galaxy dynamics.

Findings

Leo I has the highest dark matter density among classical dSphs.

The dark matter profile shows a core radius of approximately 72 pc.

Dark matter detection prospects remain consistent with previous estimates.

Abstract

Dwarf spheroidal galaxies (dSphs) are known for being strongly dominated by dark matter (DM), which makes them convenient targets for investigating the DM nature and distribution. Recently, renewed interest in the dSph Leo I has resulted from claims suggesting the presence of a central supermassive black hole (BH), with mass estimates that challenge the typical expectations for dSphs, which are generally thought to host intermediate-mass black holes (IMBHs). However, Pascale et al. 2024 presented new upper limits on the BH mass, which are consistent with the range for IMBHs, solving the concerns raised in previous studies. Building on the analysis of Pascale et al. 2024, we examine the DM properties of Leo I inferred from the dynamical models of that paper. Our results indicate that Leo I is the galaxy with the highest DM density among the classical dSphs, with a central DM density (measured at a distance of $150$ pc from the galaxy centre) $\rho_{150}=35.5_{-4.7}^{+3.8}\times10^7\,M_\odot\,$kpc$^{-3}$. The DM density profile has logarithmic slope $\gamma_{150}=-0.89_{-0.17}^{+0.21}$ at $150$ pc, in line with literature values. At smaller distances the DM distribution flattens into a core, with a core radius of $r_c=72^{+40}_{-32}$ pc. Combined with the small pericentric distance of Leo I's orbit in the Milky Way, the new estimate of $\rho_{150}$ makes Leo I decisive in the study of the anticorrelation between pericentre and central DM density, and suggests that the anticorrelation could be significantly steeper and more pronounced than previously estimated. Despite its DM dominance, Leo I does not emerge as the most favorable target for indirect DM detection: the inferred DM decay $D$ and annihilation $J$ factors, $\log D(0.5^{\circ})$ [GeV cm$^{-2}$] = $17.94_{-0.25}^{+0.17}$ and $\log J(0.5^{\circ})$ [GeV$^2$ cm$^{-5}$]= $18.13_{-0.18}^{+0.17}$ are consistent with previous estimates.