Efficient Formation of Massive Galaxies at Cosmic Dawn by Feedback-Free Starbursts

Avishai Dekel, Kartick S. Sarkar, Yuval Birnboim, Nir Mandelker, Zhaozhou Li

Published 2023-03-08Version 1

JWST observations reveal a surprising excess of luminous galaxies at $z\sim 10$, consistent with efficient conversion of the accreted gas into stars, unlike the suppression of star formation by feedback at later times. We show that the high densities and low metallicities at this epoch guarantee a high star-formation efficiency in the most massive dark-matter haloes. Feedback-free starbursts (FFBs) occur when the free-fall time is shorter than $\sim 1$ Myr, below the time for low-metallicity massive stars to develop winds and supernovae. This corresponds to a characteristic density of $\sim 3\times 10^3$cm$^{-3}$. A comparable threshold density permits a starburst by allowing cooling to star-forming temperatures in a free-fall time. The galaxies within $\sim 10^{11} M_\odot$ haloes at $z \sim 10$ are expected to have FFB densities. The halo masses allow efficient gas supply by cold streams in a halo crossing time $\sim 80$ Myr. The FFBs gradually turn all the accreted gas into stars in clusters of $\sim 10^{4-7.5} M_\odot$ within galaxies that are rotating discs or shells. The starbursting clouds are shielded against feedback from earlier stars. We predict high star-formation efficiency above thresholds in redshift and halo mass, where the density is $10^{3-4}$cm$^{-3}$. The $z\sim 10$ haloes of $\sim 10^{10.8} M_\odot$ are predicted to host galaxies of $\sim 10^{10} M_\odot$ with SFR $\sim 65 M_\odot$ yr$^{-1}$ and sub-kpc sizes. The metallicity is $\leq 0.1 Z_\odot$ with little gas, dust, outflows and hot circumgalactic gas, allowing a top-heavy IMF but not requiring it. The post-FFB evolution of compact galaxies with thousands of young clusters may have implications on black-hole growth and globular clusters at later times.