# Simulating Star Clusters Across Cosmic Time: I. Initial Mass Function,   Star Formation Rates and Efficiencies

**Authors:** Chong-Chong He (1), Massimo Ricotti (1), Sam Geen (2) ((1) Department, of Astronomy, University of Maryland, College Park, MD, US, (2) Universit\"at, Heidelberg, Zentrum f\"ur Astronomie, Institut f\"ur Theoretische, Astrophysik, Heidelberg, Germany)

arXiv: 1904.07889 · 2019-09-30

## TL;DR

This study uses advanced simulations to explore star formation in molecular clouds, reproducing observed stellar initial mass functions and star formation laws, and identifying conditions for globular cluster formation.

## Contribution

It introduces detailed radiation-magneto-hydrodynamic simulations that replicate observed stellar mass distributions and star formation efficiencies across different cloud densities and metallicities.

## Key findings

- Reproduces Salpeter slope of the initial mass function.
- Identifies star formation laws depending on gas density.
- Suggests conditions for globular cluster progenitors.

## Abstract

We present radiation-magneto-hydrodynamic simulations of star formation in self-gravitating, turbulent molecular clouds, modeling the formation of individual massive stars, including their UV radiation feedback. The set of simulations have cloud masses between $m_{\rm gas}=10^3$~M$_\odot$ to $3 \times 10^5$~M$_\odot$ and gas densities typical of clouds in the local universe ($\overline n_{\rm gas} \sim 1.8\times 10^2$~cm$^{-3}$) and 10$\times$ and 100$\times$ denser, expected to exist in high-redshift galaxies. The main results are: {\it i}) The observed Salpeter power-law slope and normalisation of the stellar initial mass function at the high-mass end can be reproduced if we assume that each star-forming gas clump (sink particle) fragments into stars producing on average a maximum stellar mass about $40\%$ of the mass of the sink particle, while the remaining $60\%$ is distributed into smaller mass stars. Assuming that the sinks fragment according to a power-law mass function flatter than Salpeter, with log-slope $0.8$, satisfy this empirical prescription. {\it ii}) The star formation law that best describes our set of simulation is $d\rho_*/dt \propto \rho_{gas}^{1.5}$ if $\overline n_{gas}<n_{cri}\approx 10^3$~cm$^{-3}$, and $d\rho_*/dt \propto \rho_{\rm gas}^{2.5}$ otherwise. The duration of the star formation episode is roughly $6$ cloud's sound crossing times (with $c_s=10$~km/s). {\it iii}) The total star formation efficiency in the cloud is $f_*=2\% (m_{\rm gas}/10^4~M_\odot)^{0.4}(1+\overline n_{\rm gas}/n_{\rm cri})^{0.91}$, for gas at solar metallicity, while for metallicity $Z<0.1$~Z$_\odot$, based on our limited sample, $f_*$ is reduced by a factor of $\sim 5$. {\it iv)} The most compact and massive clouds appear to form globular cluster progenitors, in the sense that star clusters remain gravitationally bound after the gas has been expelled.

## Full text

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## Figures

33 figures with captions in the complete paper: https://tomesphere.com/paper/1904.07889/full.md

## References

108 references — full list in the complete paper: https://tomesphere.com/paper/1904.07889/full.md

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Source: https://tomesphere.com/paper/1904.07889