MAUVE-MUSE: When Metallicity Follows or Fights Star Formation -- A Mass-Dependent Inversion in Virgo Galaxies

Abstract

Although globally-integrated studies often find that, at fixed stellar mass, high star formation rate (SFR) galaxies are relatively metal-poor while lower-SFR systems are more metal-rich, the corresponding coupling between gas-phase metallicity (Z gas) and star formation on sub-galactic scales remains poorly constrained. In this study, we analyse 14 Virgo spirals from the MAUVE-MUSE survey to revisit the resolved mass-metallicity relation (rMZR) and its secondary dependence on SFR surface density (ΣSFR) at 100\,pc scales. We construct co-spatial maps of stellar mass surface density (Σ*), ΣSFR, and oxygen abundance. MAUVE-MUSE galaxies follow a standard rMZR, but when binned by Σ*, we find a mass-dependent inversion in the Zgas-ΣSFR relation using O3N2 calibrations: the standard anti-correlation is confined to low-Σ* bins, while high-Σ* regions show a positive correlation, inverting at 10(Σ*/M\,kpc-2) 7.5-8.0. Correlated and anti-correlated Hii regions coexist within the same discs; the mass dependence emerges only when grouping spaxels by Σ*. We develop a spatially resolved gas-regulator model showing this Zgas-ΣSFR (anti-)correlation arises from competition between star-formation-driven and gas-supply-driven variability. This framework naturally extrapolates to the integrated scenario, providing a unified explanation for resolved and global relations. However, the presence and strength of the Zgas-ΣSFR (anti-)correlation depend strongly on the metallicity indicator used, highlighting the challenge of disentangling physical secondary trends within metallicity scaling relations.