The Milky Way satellite galaxy Leo T: A perturbed cored dwarf

TL;DR

This study uses hydrodynamic simulations to understand the complex gas and stellar dynamics of the Leo T dwarf galaxy, revealing how dark matter profiles and stellar winds influence observed offsets and long-term substructures.

Contribution

It demonstrates that cored dark matter profiles and stellar winds are key to reproducing observed features and long-lived substructures in Leo T, advancing understanding of low-mass galaxy evolution.

Findings

Cored dark matter profiles produce long-lasting stellar and gas offsets.

Stellar winds interacting with HI generate observed gas-star offsets.

Non-equilibrium substructures can persist in cored low-mass dwarfs.

Abstract

The impact of the dynamical state of gas-rich satellite galaxies at the early moments of their infall into their host systems and the relation to their quenching process are not completely understood at the low-mass regime. Two such nearby systems are the infalling Milky Way (MW) dwarfs Leo~T and Phoenix located near the MW virial radius at $414 {\rm kpc}\,(1.4 R_{\rm vir})$, both of which present intriguing offsets between their gaseous and stellar distributions. Here we present hydrodynamic simulations with {\sc ramses} to reproduce the observed dynamics of Leo~T: its $80{\rm pc}$ stellar-HI offset and the 35{\rm pc} offset between its older ($\gtrsim 5{\rm Gyr}$) and younger ($\sim\!200\!-\!1000{\rm Myr}$) stellar population. We considered internal and environmental properties such as stellar winds, two HI components, cored and cuspy dark matter profiles, and different satellite orbits considering the MW circumgalactic medium. We find that the models that best match the observed morphology of the gas and stars include mild stellar winds that interact with the HI generating the observed offset, and dark matter profiles with extended cores. The latter allow long oscillations of the off-centred younger stellar component, due to long mixing timescales ($\gtrsim200 {\rm Myr}$), and the slow precession of near-closed orbits in the cored potentials; instead, cuspy and compact cored dark matter models result in the rapid mixing of the material ($\lesssim 200{\rm Myr}$). These models predict that non-equilibrium substructures, such as spatial and kinematic offsets, are likely to persist in cored low-mass dwarfs and to remain detectable on long timescales in systems with recent star formation.