# What drives gravitational instability in nearby star-forming spirals?   The impact of CO and HI velocity dispersions

**Authors:** Alessandro B. Romeo, Keoikantse Moses Mogotsi

arXiv: 1701.02138 · 2017-05-31

## TL;DR

This study investigates how velocity dispersions of molecular and atomic gas influence gravitational instability in star-forming galaxy discs, revealing that stellar self-gravity primarily drives large-scale instabilities.

## Contribution

It provides a detailed analysis of the impact of CO and HI velocity dispersions on galaxy disc stability, emphasizing the dominant role of stellar self-gravity at kiloparsec scales.

## Key findings

- Radial variations of sigma_CO and sigma_HI have a weak effect on local stability.
- The characteristic instability scale is ten times larger than the Toomre length.
- Stars and molecular gas are strongly coupled during instability onset.

## Abstract

The velocity dispersion of cold interstellar gas, sigma, is one of the quantities that most radically affect the onset of gravitational instabilities in galaxy discs, and the quantity that is most drastically approximated in stability analyses. Here we analyse the stability of a large sample of nearby star-forming spirals treating molecular gas, atomic gas and stars as three distinct components, and using radial profiles of sigma_CO and sigma_HI derived from HERACLES and THINGS observations. We show that the radial variations of sigma_CO and sigma_HI have a weak effect on the local stability level of galaxy discs, which remains remarkably flat and well above unity, but is low enough to ensure (marginal) instability against non-axisymmetric perturbations and gas dissipation. More importantly, the radial variation of sigma_CO has a strong impact on the size of the regions over which gravitational instabilities develop, and results in a characteristic instability scale that is one order of magnitude larger than the Toomre length of molecular gas. Disc instabilities are driven, in fact, by the self-gravity of stars at kpc scales. This is true across the entire optical disc of every galaxy in the sample, with few exceptions. In the linear phase of the disc instability process, stars and molecular gas are strongly coupled, and it is such a coupling that ultimately triggers local gravitational collapse/fragmentation in the molecular gas.

## Full text

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## Figures

6 figures with captions in the complete paper: https://tomesphere.com/paper/1701.02138/full.md

## References

85 references — full list in the complete paper: https://tomesphere.com/paper/1701.02138/full.md

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Source: https://tomesphere.com/paper/1701.02138