Ghostly Halos in Dwarf Galaxies: Constraints on the Star Formation Efficiency before Reionization

TL;DR

This study uses semi-analytical simulations to analyze ghostly stellar halos in dwarf galaxies, constraining star formation efficiency before reionization and providing insights into galaxy formation at high redshift.

Contribution

It introduces a model linking ghostly halo properties to star formation efficiency in fossil galaxies, constrained by observations of Local Group dwarfs.

Findings

Star formation efficiency in halos of 10^7-10^9 M_sun is ~0.05%-0.1% at z~6.

Extended stellar halos are consistent with fossil galaxy debris.

Potential increase in star formation efficiency at lower halo masses (~10^6-10^7 M_sun).

Abstract

Stellar halos observed around normal galaxies are extended and faint stellar structures formed by debris of tidally disrupted dwarf galaxies accreted over time by the host galaxy. Around dwarf galaxies, these stellar halos may not exist if all the accreted satellites are dark halos without stars. However, if a stellar halo is found in sufficiently small mass dwarfs, the whole stellar halo is composed of tidal debris of fossil galaxies, and we refer to it as ghostly halo. Fossil galaxies are called so because they formed most of their stars before the epoch of reionization, and have been identified as the ultra-faint dwarf galaxies found around the Milky Way and M31. In this paper we carry out semi-analytical simulations to characterize the sizes and stellar masses of ghostly stellar halos in dwarf galaxies as a function of their dark matter halo mass. By comparing the models to observations of six isolated dwarf galaxies in the Local Group showing evidence of extended stellar halos, we are able to constrain the star formation efficiency in fossil galaxies. We find that at redshift z~6, dark matter halos in the mass range 10^7-10^9 M_sun have a mean star formation efficiency f_* = M_*/M_{dm} ~ 0.05%-0.1% nearly constant as a function of the dark matter halo mass. There is a tentative indication of a sharp increase of f_* at M_{dm} ~ 10^6-10^7 M_sun, but it is very uncertain and based on only one dwarf galaxy (Leo~T).