MSA-3D: Connecting the Chemical and Kinematic Structures of Galaxies at z 1

Abstract

We investigate the connection between ionized gas kinematics and gas-phase metallicity gradients in 21 star-forming galaxies at 0.5 < z < 1.7 from the MSA-3D survey, using spatially resolved JWST/NIRSpec slit-stepping observations. Galaxy kinematics are characterized by the ratio of rotational velocity to intrinsic velocity dispersion, v/σ, measured at 1.5\,Re, where Re is the effective radius. We find that dynamically hotter disks exhibit systematically flatter metallicity gradients, with a moderate anti-correlation between metallicity gradient and v/σ (Pearson r=-0.43, p=0.05) and a linear fit yields a slope of 0.005 dex per dex in v/σ, weaker than the dependence on stellar mass. A significantly stronger anti-correlation is observed with Re/σ, interpreted as a proxy for the radial mixing timescale (r=-0.59, p=0.005), indicating that cumulative radial mixing more directly regulates chemical stratification. The metallicity gradients in our sample are uniformly shallow, indicating that efficient turbulent mixing in kinematically settled disks regulates the chemical structure of typical star-forming galaxies at z1.