Pervasive Cavity-Ring Structure for Star Formation in Dwarf Irregular Galaxies

TL;DR

This study uses HI imaging to analyze star formation in dwarf irregular galaxies, revealing large cavities, dispersed clouds, and slow, sequential star formation processes distinct from spiral galaxies.

Contribution

It identifies the pervasive cavity-ring structures in dwarf irregulars and compares their star formation efficiency and dynamics to those in spiral galaxies.

Findings

Cavities extend for a radial scalelength with circular or slightly sheared shapes.

Gas consumption time is approximately 3.2 Gyr, similar to spiral galaxy molecular clouds.

Star formation proceeds slowly and sequentially in dispersed clouds and expanding cavities.

Abstract

Unsharp-mask images of HI emission from 36 dwarf irregular (dIrr) galaxies illustrate star formation in dispersed clouds and on the rims of large cavities. The cavities can extend for a radial scalelength and typically have circular or slightly sheared forms. The average surface density of cloud peaks is ~20 Msun/pc2, and, combined with their average FUV star formation rate, suggests a gas consumption time of ~3.2 Gyr. Vertical hydrostatic equilibrium calculations for 24 of these dIrrs give a typical scale height of ~400 pc, which combines with the gas and star formation surface densities to suggest an efficiency per free fall time of ~1%. These values are comparable to those in the molecular clouds of spiral galaxies, suggesting the primary difference between clouds is the presence of CO at higher metallicity in the spirals. U-B color images of the dIrrs suggest that cavity ages range between 10^7 and 10^8 years, with the longer times explaining the common lack of bright OB associations in their centers and their low expansion speeds. Most are circular because the shear time exceeds 100 Myr, although some of the HI has spiral structure. These observations suggest that star formation in dIrrs proceeds slowly in a sequential fashion in dispersed clouds and on the periphery of giant cavities that move and expand during the ~50 Myr supernova era of the previous generation. In contrast, spiral galaxies have shear times 10 times shorter and more important stellar dynamics that compresses the gas into filaments.