Astraeus V: The emergence and evolution of metallicity scaling relations during the Epoch of Reionization
Abstract
In this work, we have implemented a detailed physical model of galaxy chemical enrichment into the Astraeus (semi-numerical rAdiative tranSfer coupling of galaxy formaTion and Reionization in N-body dark matter simUlationS) framework which couples galaxy formation and reionization in the first billion years. Simulating galaxies spanning over 2.5 orders of magnitude in halo mass with Mh 108.9-11.5 M (Mh 108.9-12.8 M) at z 10 ~ (5), we find: (i) smooth-accretion of metal-poor gas from the intergalactic medium (IGM) plays a key role in diluting the interstellar medium (ISM) metallicity which is effectively restored due to self-enrichment from star formation; (ii) a redshift averaged gas-mass loading factor that depends on the stellar mass as ηg ≈ 1.38 (M*/1010 M)-0.43; (iii) the mass-metallicity relation is already in place at z 10 and shows effectively no redshift evolution down to z 5; (iv) for a given stellar mass, the metallicity decreases with an increase in the star formation rate (SFR); (v) the key properties of the gas-phase metallicity (in units of 12+log(O/H), stellar mass, SFR and redshift are linked through a high-redshift fundamental plane of metallicity (HFPZ) for which we provide a functional form; (vi) the mass-metallicity-SFR relations are effectively independent of the reionization radiative feedback model for M* ≥ 106.5 M galaxies; (vii) while low-mass galaxies (Mh ≤ 109 M) are the key contributors to the metal budget of the IGM at early times, higher mass halos provide about 50% of the metal budget at lower-redshifts.
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