Tidal disruption of dwarf spheroidal galaxies: the strange case of Crater II

TL;DR

This paper investigates the tidal disruption of dwarf spheroidal galaxies, especially Crater II, using analytic and numerical models to explain its unusual velocity dispersion and size, emphasizing dark matter profile effects.

Contribution

It demonstrates that heavy tidal disruption explains Crater II's properties and highlights the role of dark matter profile shapes in its evolution within standard galaxy formation theory.

Findings

Tidal disruption suppresses velocity dispersion in dwarf galaxies.

Cored dark matter profiles better match Crater II's observed size evolution.

Tidal effects shape galaxy morphology, leading to prolate central regions.

Abstract

Dwarf spheroidal galaxies of the Local Group obey a relationship between the line-of-sight velocity dispersion and half-light radius, although there are a number of dwarfs that lie beneath this relation with suppressed velocity dispersion. The most discrepant of these (in the Milky Way) is the `feeble giant' Crater II. Using analytic arguments supported by controlled numerical simulations of tidally-stripped flattened two-component dwarf galaxies, we investigate interpretations of Crater II within standard galaxy formation theory. Heavy tidal disruption is necessary to explain the velocity-dispersion suppression which is plausible if the proper motion of Crater II is $(\mu_{\alpha*},\mu_\delta)=(-0.21\pm0.09,-0.24\pm0.09)\mathrm{mas\,yr}^{-1}$. Furthermore, we demonstrate that the velocity dispersion of tidally-disrupted systems is solely a function of the total mass loss even for weakly-embedded and flattened systems. The half-light radius evolution depends more sensitively on orbital phase and the properties of the dark matter profile. The half-light radius of weakly-embedded cusped systems rapidly decreases producing some tension with the Crater II observations. This tension is alleviated by cored dark matter profiles, in which the half-light radius can grow after tidal disruption. The evolution of flattened galaxies is characterised by two competing effects: tidal shocking makes the central regions rounder whilst tidal distortion produces a prolate tidally-locked outer envelope. After $\sim70$ per cent of the central mass is lost, tidal distortion becomes the dominant effect and the shape of the central regions of the galaxy tends to a universal prolate shape irrespective of the initial shape.