On bursty star formation during cosmological reionization -- influence on the metal and dust content of low-mass galaxies

Abstract

Observations indicate that high-redshift galaxies undergo episodic star formation bursts, driving strong outflows that expel gas and suppress accretion. We investigate the consequences for metal and dust content of galaxies at z ≥ 5 using our semi-analytical model, ASHVINI. We track gas-phase and stellar metallicities (Z g, Z) and dust mass (M d) in dark matter haloes spanning M halo = 106-1011 M, comparing continuous and bursty star formation scenarios - which reflect underlying assumptions of instantaneous and delayed feedback - and we allow for metallicity-dependent feedback efficiency. Delayed feedback induces oscillations in Z g and Z, with Z g declining sharply at low stellar and halo masses; the mass scale of this decline increases toward lower redshift. Reionization introduces significant scatter in Z g, producing an upturn followed by rapid decline. Metallicity-dependent feedback moderates this decline at z=7 - 10, flattening the Z g-mass relation to 0.03-0.04\, Z. Dust production tracks Z g but is sensitive to burst history, causing delayed enrichment. Our results show that burst-driven feedback decouples Z g and Z, imprints intrinsic scatter in mass-metallicity relations, and delays dust growth. These effects are strongest in low-mass halos (M halo 107 M), where shallow potentials amplify the impact of feedback. Our results are consistent with recent hydrodynamical and semi-analytical simulations and provide context for interpreting JWST (James Webb Space Telescope) metallicity and dust measurements, highlighting the importance of episodic star formation in early galaxy chemical evolution.