Spatially resolved gas-phase metallicity at z~2-3 with JWST/NIRISS

TL;DR

This study presents the first spatially resolved gas-phase metallicity maps of multiple galaxies at z~2-3 using JWST/NIRISS, revealing insights into chemical evolution, ionization sources, and feedback processes.

Contribution

It introduces a novel method for demarcating star formation and AGN activity in high-redshift galaxies without resolved H-alpha, and provides new metallicity gradient measurements.

Findings

No clear mass-metallicity gradient trend observed.

Weak correlation between metallicity and SFR maps suggests metal-transport timescales increase with stellar mass.

High-z galaxies may not have entered the accretion-dominated phase.

Abstract

Spatially resolved gas-phase metallicity maps are a crucial element in understanding the chemical evolution of galaxies. We present spatially resolved metallicity maps obtained from NIRISS/WFSS observations. This is the first such work presenting multiple individual galaxies. We investigate the source of ionisation, metallicity and its relation to star-formation in a spatially-resolved sense for a sample of eight galaxies -- four from JWST-PASSAGE and four from GLASS-JWST ERS. All but one galaxy are in the redshift range $1.9 \leq z \leq 2$, the outlier being at $z = 3.1$. Our sample covers a range of $8.0 <$ \logM $< 9.5$ in stellar mass, $0.2 <$ $\log{\rm{(SFR}}$/\Msunpyr) $< 1.1$ in star-formation rate (SFR) and $7.8 <$ \logOH $< 9.0$ in global metallicity. As a solution to the challenge of SF-AGN demarcation in absence of resolved \halpha, we present a new SF-demarcation line in the \textit{OHNO} parameter space based on MAPPINGS v5.1 publicly available \hii region model grids. We present the mass-metallicity gradient relation for our sample, which showed no clear trend with stellar mass, perhaps hinting at the fact that the high-$z$ galaxies have not yet started their accretion dominated phase. By interpreting the correlation between spatially resolved metallicity and SFR maps as a proxy for effective timescales of metal-transport in galaxies, we find a weak trend such that this timescale increases with stellar mass, implying a more effective feedback in lower mass galaxies.