The physical origin of positive metallicity radial gradients in high-redshift galaxies: insights from the FIRE-2 cosmological hydrodynamic simulations

Using the FIRE-2 cosmological zoom-in simulations, we investigate the temporal evolution of gas-phase metallicity radial gradients of Milky Way-mass progenitors in the redshift range of $0.4<z<3$. We pay special attention to the occurrence of positive (i.e. inverted) metallicity gradients -- where metallicity increases with galactocentric radius. This trend, contrary to the more commonly observed negative radial gradients, has been frequently seen in recent spatially resolved grism observations. The occurrence rate of positive gradients in FIRE-2 is about $\sim10\%$ for $0.4<z<3$, and $\sim16\%$ at higher redshifts ($1.5<z<3$), broadly consistent with observations. Moreover, we investigate the correlations among galaxy metallicity gradient, stellar mass, star formation rate (SFR), and degree of rotational support. Our results show that galaxies with lower mass, higher specific SFR (sSFR), and more turbulent disks are more likely to exhibit positive metallicity gradients. The FIRE-2 simulations show evidence for positive gradients that occur both before and/or after major episodes of star formation, manifesting as sharp rises in a galaxy's star-formation history. Positive gradients occurring before major star-formation episodes are likely caused by metal-poor gas inflows, whereas those appearing afterwards often result from metal-enriched gas outflows, driven by strong stellar feedback. Our results support the important role of stellar feedback in governing the chemo-structural evolution and disk formation of Milky Way-mass galaxies at the cosmic noon epoch.
Comment: 17 pages, 9 figures