MEGATRON: how the first stars create an iron metallicity plateau in the smallest dwarf galaxies

Abstract

We study the stellar mass-iron metallicity relation of dwarf galaxies in the new high-resolution MEGATRON cosmological radiation-hydrodynamics simulations. These simulations model galaxy formation up to z≈8 in a region that will collapse into a Milky-Way-like galaxy at z=0, while self-consistently tracking Population III and II (Pop.~III, Pop.~II) star formation, feedback and chemical enrichment. MEGATRON dwarf galaxies are in excellent agreement with the observed stellar mass-metallicity relation at z=0, including an over-abundance of dwarfs along a flat plateau in metallicity ( [Fe/H] ≈ -2.5) at low stellar masses (M ≤ 105 \, M). We tie this feature to the chemical enrichment of dwarf galaxies by Pop.~III pair-instability supernova (PISN) explosions. The strong Lyman-Werner background (LW) from the protogalaxy ensures that PISNe occur in haloes massive enough (≈ 107\, M) to retain their ejecta. We also predict a tail of ≈ 20\% of iron-deficient ( [Fe/H] ≤ - 3) dwarf galaxies. We show that both plateau and tail (i) are robust to large variations in Pop.~II feedback assumptions, and (ii) survive in bound satellites surrounding the central galaxy at z=0.

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