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Galaxy evolution emerges from the balance between cosmic gas accretion, fueling star formation, and supernova (SN) feedback, regulating the metal enrichment. Hence, the stellar mass (M_*) - gas metallicity relation (MZR) is key to understand the physics of galaxies. High-quality JWST data enable accurate measurements of the MZR up to redshift z=10. Our aims are to understand the observed MZR, its connection with the star formation rate (SFR), the role played by SFR stochasticity, and how it is regulated by SN feedback. We compare the MZR from the JADES, CEERS, and UNCOVER surveys, which comprise about 180 galaxies at z=3-10 with 10⁶<M_*/M_<10^10, with 200 galaxies from the SERRA cosmological simulations. To interpret the MZR, we develop a minimal model for galaxy evolution that includes: cosmic accretion modulated with an amplitude A₁₀₀ on 100 Myr; a time delay td between SFR and SN; SN-driven outflows with a varying mass loading factor ₒ₍. Using our minimal model, we find the observed mean MZR is reproduced by weak outflows (ₒ₍=1/4), in line with findings from JADES. Matching the observed MZR dispersion requires td=20 Myr and a A₁₀₀=1/3 modulation of the accretion rate. Successful models have low stochasticity (ₒ₅ₑ=0. 2), yielding a MZR dispersion of ₙ=0. 2. Such values are close but lower than SERRA predictions (ₒ₅ₑ=0. 24, ₙ=0. 3), clarifying why SERRA show no clear MZR trend and some tension with the observations. As the MZR is very sensitive to SFR stochasticity, models predicting high r. m. s. values (ₒ₅ₑ=0. 5) result in a ``chemical chaos'' (i. e. ₙ=1. 4), virtually destroying the MZR. As a consequence, invoking a highly stochastic SFR (ₒ₅ₑ=0. 8) to explain the overabundance of bright, super-early galaxies leads to inconsistencies with the observed MZR.
Pallottini et al. (Wed,) studied this question.