Star Formation in Dwarf Galaxies of the Nearby Centaurus A Group

TL;DR

This study investigates star formation in 17 dwarf irregular galaxies within the Centaurus A Group, revealing that star formation rates are unaffected by local environment and identifying transition dwarfs that challenge existing transformation theories.

Contribution

It provides new insights into the environmental independence of star formation in dwarf irregulars and introduces the concept of inhomogeneous IGM influencing galaxy evolution.

Findings

Star formation rates in dIs are independent of local environment.

Transition dwarfs have intermediate distances and contain cold gas but no current star formation.

Inhomogeneous IGM may explain dwarf galaxy transformations at large distances.

Abstract

We present Halpha narrow-band imaging of 17 dwarf irregular galaxies (dIs) in the nearby Centaurus A Group. Although all large galaxies of the group have a current or recent enhanced star formation episode, the dIs have normal star formation rates and do not contain a larger fraction of dwarf starbursts than other nearby groups. Relative distances between dIs and larger galaxies of the group can be computed in 3D since most of them have now fairly accurately known distances. We find that the dI star formation rates do not depend on local environment, and in particular they do not show any correlation with the distance of the dI to the nearest large galaxy of the group. There is a clear morphology-density relation in the Centaurus A Group, similarly to the Sculptor and Local Groups, in the sense that dEs/dSphs tend to be at small distances from the more massive galaxies of the group, while dIs are on average at larger distances. We find four transition dwarfs in the Group, dwarfs that show characteristics of both dE/dSphs and dIs, and which contain cold gas but no current star formation. Interestingly the transition dwarfs have an average distance to the more massive galaxies which is intermediate between those of the dEs/dSphs and dIs, and which is quite large: 0.54 +- 0.31 Mpc. This large distance poses some difficulty for the most popular scenarios proposed for transforming a dI into a dE/dSph (ram-pressure with tidal stripping or galaxy harassment). If the observed transition dwarfs are indeed missing links between dIs and dE/dSphs, their relative isolation makes it less likely to have been produced by these mechanisms. We propose that an inhomogeneous IGM containing higher density clumps would be able to ram-pressure stripped the dIs at such large distances.