Unbiased constraints on ultralight axion mass from dwarf spheroidal galaxies

TL;DR

This study uses realistic mock data and chemodynamical modeling to derive unbiased constraints on ultralight axion mass from dwarf spheroidal galaxies, challenging previous bounds and considering baryonic effects.

Contribution

It introduces a method to obtain unbiased axion mass constraints by analyzing chemodynamical components and applies it to Fornax and Sculptor dSphs, highlighting the impact of halo profiles.

Findings

Constraints: $m_a<0.4\times 10^{-22}$ eV at 97.5% confidence

Core radii bounds: $r_c>1.5$ kpc (Fornax), $r_c>1.2$ kpc (Sculptor)

Tension with satellite counts from subhalo mass function

Abstract

It has been suggested that the internal dynamics of dwarf spheroidal galaxies (dSphs) can be used to test whether or not ultralight axions with $m_a\sim 10^{-22}\text{eV}$ are a preferred dark matter candidate. However, comparisons to theoretical predictions tend to be inconclusive for the simple reason that while most cosmological models consider only dark matter, one observes only baryons. Here we use realistic kinematic mock data catalogs of Milky Way dSph's to show that the "mass-anisotropy degeneracy" in the Jeans equations leads to biased bounds on the axion mass in galaxies with unknown dark matter halo profiles. In galaxies with multiple chemodynamical components this bias can be partly removed by modelling the mass enclosed within each subpopulation. However, analysis of the mock data reveals that the least-biased constraints on the axion mass result from fitting the luminosity-averaged velocity dispersion of the individual chemodynamical components directly. Applying our analysis to two dSph's with reported stellar subcomponents, Fornax and Sculptor, and assuming that the halo profile has not been acted on by baryons, yields core radii $r_{c}>1.5$ kpc and $r_c> 1.2$ kpc respectively, and $m_a<0.4\times 10^{-22}\text{eV}$ at 97.5\% confidence. These bounds are in tension with the number of observed satellites derived from simple (but conservative) estimates of the subhalo mass function in Milky Way-like galaxies. We discuss how baryonic feedback might affect our results, and the impact of such a small axion mass on the growth of structures in the Universe.