A Strong Stellar Age-Metallicity Gradient Relation in Nearby Dwarf Galaxies Driven by Stellar Migration and Environmental Quenching

Abstract

Stellar metallicity gradients (∇[Z/H]) provide a fossil record of the assembly history of galaxies. We present an analysis of ∇[Z/H] for 90 nearby low-mass galaxies using VLT/MUSE IFU spectroscopy, spanning stellar masses from 106.5 to 1010 M (median 108.5 M) and significantly extending the mass coverage of existing IFU surveys into the classical dwarf regime. Our primary finding is a robust negative correlation between ∇[Z/H] and light-weighted stellar age (|r| 0.7) measured out to 2× effective radius: older dwarf galaxies have steeper (more negative) gradients. This holds regardless of stellar mass, structural compactness, or large-scale environment (group/field), and is strongest in the intermediate-mass regime (8.2 M/M9.0). The slope of the age-∇[Z/H] relation is close to that in the FIRE-2 simulations, indicating that stellar radial migration driven by feedback-induced potential fluctuations may be fundamental in dwarf evolution. But this apparent consistency is likely coincidental given the simulations' overly efficient feedback and chemical mixing. On the other hand, the H\,i deficiency parameter, an indicator of past environmental stripping, shows a moderate yet highly significant correlation with ∇[Z/H], second only to stellar age in strength: galaxies with higher H\,i deficiency tend to have more negative gradients, strongly indicating that environment-driven outside-in quenching and the ensuing gradual truncation of metal enrichment re-shape the stellar metallicity distribution. Our analysis suggests that the chemical evolution of dwarf galaxies likely arises from a synergy of feedback-driven dynamical heating and external environmental processing, though only the latter has robust observational support.