# Cloud Scale ISM Structure and Star Formation in M51

**Authors:** Adam K. Leroy, Eva Schinnerer, Annie Hughes, J. M. Diederik Kruijssen,, Sharon Meidt, Andreas Schruba, Jiayi Sun, Frank Bigiel, Gonzalo Aniano,, Guillermo A. Blanc, Alberto Bolatto, M\'elanie Chevance, Dario Colombo, Molly, Gallagher, Santiago Garcia-Burillo, Carsten Kramer, Miguel Querejeta, Jerome, Pety, Todd A. Thompson, Antonio Usero

arXiv: 1706.08540 · 2017-09-06

## TL;DR

This study investigates the molecular gas structure and star formation efficiency in M51 at various scales, revealing that self-gravity strongly influences star formation rates and efficiency, with results challenging some existing turbulent star formation models.

## Contribution

It provides a detailed analysis of molecular gas properties and star formation in M51 at high resolution, highlighting the role of self-gravity and introducing new correlations between gas parameters and star formation.

## Key findings

- Star formation efficiency per free-fall time is about 0.3-0.36%, lower than in local clouds.
- Self-gravity parameter b strongly predicts star formation rate, with a inverse relation to depletion time.
- Gas with higher self-gravity forms stars more efficiently, especially in certain galaxy regions.

## Abstract

We compare the structure of molecular gas at $40$ pc resolution to the ability of gas to form stars across the disk of the spiral galaxy M51. We break the PAWS survey into $370$ pc and $1.1$ kpc resolution elements, and within each we estimate the molecular gas depletion time ($\tau_{\rm Dep}^{\rm mol}$), the star formation efficiency per free fall time ($\epsilon_{\rm ff}$), and the mass-weighted cloud-scale (40 pc) properties of the molecular gas: surface density, $\Sigma$, line width, $\sigma$, and $b\equiv\Sigma/\sigma^2\propto\alpha_{\rm vir}^{-1}$, a parameter that traces the boundedness of the gas. We show that the cloud-scale surface density appears to be a reasonable proxy for mean volume density. Applying this, we find a typical star formation efficiency per free-fall time, $\epsilon_{ff} \left( \left< \Sigma_{40pc} \right> \right) \sim 0.3{-}0.36\%$, lower than adopted in many models and found for local clouds. More, the efficiency per free fall time anti-correlates with both $\Sigma$ and $\sigma$, in some tension with turbulent star formation models. The best predictor of the rate of star formation per unit gas mass in our analysis is $b \equiv \Sigma / \sigma^2$, tracing the strength of self gravity, with $\tau_{\rm Dep}^{\rm mol} \propto b^{-0.9}$. The sense of the correlation is that gas with stronger self-gravity (higher $b$) forms stars at a higher rate (low $\tau_{\rm Dep}^{\rm mol}$). The different regions of the galaxy mostly overlap in $\tau_{\rm Dep}^{\rm mol}$ as a function of $b$, so that low $b$ explains the surprisingly high $\tau_{\rm Dep}^{\rm mol}$ found towards the inner spiral arms found by by Meidt et al. (2013).

## Full text

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## Figures

15 figures with captions in the complete paper: https://tomesphere.com/paper/1706.08540/full.md

## References

106 references — full list in the complete paper: https://tomesphere.com/paper/1706.08540/full.md

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Source: https://tomesphere.com/paper/1706.08540