Mini-quenching of z=4-8 galaxies by bursty star formation

Abstract

The recent reported discovery of a low-mass z=5.2 and an intermediate-mass z=7.3 quenched galaxy with JWST/NIRSpec is the first evidence of halted star formation above z≈ 5. Here we show how bursty star formation at z=4-8 gives rise to temporarily quenched, or mini-quenched galaxies in the mass range M = 107-109 \ M using four models of galaxy formation: the periodic box simulation IllustrisTNG, the zoom-in simulations VELA and FirstLight and an empirical halo model. The main causes for mini-quenching are stellar feedback, lack of gas accretion onto galaxies and galaxy-galaxy interactions. The abundance of (mini-)quenched galaxies agrees across the models: the population first appears below z≈ 8, after which their proportion increases with cosmic time, from 0.5-1.0% at z=7 to 2-4% at z=4, corresponding to comoving number densities of 10-5 Mpc-3 and 10-3 Mpc-3, respectively. These numbers are consistent with star formation rate duty cycles inferred for VELA and FirstLight galaxies. Their star formation histories (SFHs) suggest that mini-quenching at z=4-8 is short-lived with a duration of 20-40 Myr, which is close to the free-fall timescale of the inner halo. However, mock spectral energy distributions of mini-quenched galaxies in IllustrisTNG and VELA do not match JADES-GS-z7-01-QU photometry, unless their SFHs are artificially altered to be more bursty on timescales of 40 Myr. Studying mini-quenched galaxies might aid in calibrating sub-grid models governing galaxy formation, as these may not generate sufficient burstiness at high redshift to explain the SFH inferred for JADES-GS-z7-01-QU.