The <scp>thesan-zoom</scp> project: central starbursts and inside-out quenching govern galaxy sizes in the early Universe
William McClymont, Sandro Tacchella, Aaron Smith, Rahul Kannan, Ewald Puchwein, Josh Borrow, Enrico Garaldi, Laura C. Keating, Mark Vogelsberger, Oliver Zier, Xuejian Shen, Filip Popovic
Abstract
ABSTRACT We explore the evolution of galaxy sizes at high redshift ($3&lt; z &lt; 13$) using the high-resolution thesan-zoom radiation-hydrodynamics simulations, focusing on the mass range of $10^6\, \mathrm{M}_{\odot } &lt; \mathit{M}_{\ast } &lt; 10^{10}\, \mathrm{M}_{\odot }$. Our analysis reveals that galaxy size growth is tightly coupled to bursty star formation. Galaxies above the star-forming main sequence tend to form stars in a central starburst, which decreases their radial size. These galaxies quench inside-out, causing spatially extended star formation and increasing their radial size, leading to oscillatory behaviour around the size–mass relation. Notably, we find a positive intrinsic size–mass relation at high redshift, consistent with observations but in tension with large-volume simulations. We attribute this discrepancy to the bursty star formation captured by our multiphase interstellar medium framework, but missing from simulations using the effective equation-of-state approach with hydrodynamically decoupled feedback. We also find that the normalization of the size–mass relation follows a double power law as a function of redshift, with a break at $z\approx 6$, because the majority of galaxies at $z&gt;6$ show rising star-formation histories, and therefore are in a compaction phase. We demonstrate that H $\alpha$ emission is systematically extended relative to the UV continuum by a median factor of 1.7, consistent with recent James Webb Space Telescope studies. However, in contrast to previous interpretations that link extended H $\alpha$ sizes to inside-out growth, we find that Lyman-continuum (LyC) emission is spatially disconnected from H $\alpha$. Instead, a simple Strömgren sphere argument reproduces observed trends, suggesting that extreme LyC production during central starbursts is the primary driver of extended nebular emission.