Angular momentum of dwarf galaxies

TL;DR

This study measures the angular momentum of void dwarf galaxies, finding high specific angular momentum comparable to other dwarfs, with implications for galaxy formation and evolution mechanisms.

Contribution

It provides new measurements of baryonic mass and specific angular momentum for 11 void dwarf galaxies, and analyzes their relation to environment and galaxy properties.

Findings

Void dwarf galaxies have high specific angular momentum.

No dependence of angular momentum on large-scale environment.

A baryonic mass threshold of ~10^9.1 M_sun is linked to increased angular momentum.

Abstract

Mass and specific angular momentum are two fundamental physical parameters of galaxies. We present measurements of the baryonic mass and specific angular momentum of 11 void dwarf galaxies derived from neutral hydrogen (H{\sc i}) synthesis data. Rotation curves were measured using 3D and 2D tilted ring fitting routines, and the derived curves generally overlap within the error bars, except in the central regions where, as expected, the 3D routines give steeper curves. The specific angular momentum of void dwarfs is found to be high compared to an extrapolation of the trends seen for higher mass bulge-less spirals, but comparable to that of other dwarf irregular galaxies that lie outside of voids. As such, our data show no evidence for a dependence of the specific angular momentum on the large scale environment. Combining our data with the data from the literature, we find a baryonic threshold of $\sim 10^{9.1}~M_{\odot}$ for this increase in specific angular momentum. Interestingly, this threshold is very similar to the mass threshold below which the galaxy discs start to become systematically thicker. This provides qualitative support to the suggestion that the thickening of the discs, as well as the increase in specific angular momentum, are both results of a common physical mechanism, such as feedback from star formation. Quantitatively, however, the amount of star formation observed in our dwarfs appears insufficient to produce the observed increase in specific angular momentum. It is hence likely that other processes, such as cold accretion of high angular momentum gas, also play a role in increasing the specific angular momentum.