Metallicity Dependence of Pressure-Regulated Feedback-Modulated Star Formation in the TIGRESS-NCR Simulation Suite
Abstract
We present a new simulation suite for the star-forming interstellar medium (ISM) in galactic disks using the TIGRESS-NCR framework. Distinctive aspects of our simulation suite are: (1) sophisticated and comprehensive numerical treatments of essential physical processes including magnetohydrodynamics, self-gravity, and galactic differential rotation, as well as photochemistry, cooling, and heating coupled with ray-tracing UV radiation transfer and resolved supernova feedback and (2) wide parameter coverage including metallicity over Z' Z/Z0.1-3, gas surface density gas5-150 M pc-2, and stellar surface density star 1-50 M pc-2. The range of emergent star formation rate surface density is SFR 10-4-0.5 M kpc-2yr-1 and ISM total midplane pressure is P tot/kB=103-106 cm-3K, with P tot equal to the ISM weight W. For given gas and star, we find SFR Z'0.3. We provide an interpretation based on the pressure-regulated feedback-modulated (PRFM) star formation theory. We characterize feedback modulation in terms of the yield , defined as the ratio of each stress to SFR. The thermal feedback yield varies sensitively with both weight and metallicity as th W-0.46Z'-0.53, while the combined turbulent and magnetic feedback yield shows weaker dependence turb+mag W-0.22Z'-0.18. The reduction in SFR at low metallicity is due mainly to enhanced thermal feedback yield, resulting from reduced attenuation of UV radiation. With the metallicity-dependent calibrations we provide, PRFM theory can be used for a new subgrid star formation prescription in cosmological simulations where the ISM is unresolved.
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