📝 SummarXiv

Abstract

Spatially resolved stellar populations of massive, quiescent galaxies at cosmic noon provide powerful insights into star-formation quenching and stellar mass assembly mechanisms. Previous photometric work has revealed that the cores of these galaxies are redder than their outskirts. However, spectroscopy is needed to break the age-metallicity degeneracy and uncover the driver of these colour gradients. Here, we derive age and elemental abundance gradients for 8 distant ($1.2 \lesssim z \lesssim 2.2$), massive ($10.3\lesssim\log({\rm M}_*/{\rm M}_\odot)\lesssim 11.1$), quiescent galaxies, by fitting full-spectrum models to ultra-deep NIRSpec-MSA spectroscopy from the JWST-SUSPENSE survey. We find that these galaxies have negative age, positive [Mg/H] and [Mg/Fe], and flat [Fe/H] gradients, implying that galaxy cores are older and Mg-deficient compared to galaxy outskirts. The age gradients indicate inside-out quenching, while the Mg-deficient cores suggest rapid gas expulsion as the central quenching mechanism. Thus, galaxy cores formed faster and quenched more efficiently than their outskirts. In this scenario, however, our [Fe/H] and [Mg/Fe] gradients are still puzzling. Our results contrast lower-redshift studies, which find flat age and [Mg/Fe] gradients and negative metallicity gradients. Additionally, we find a positive trend between age gradients and rotational support, and marginal trends between gradients and galaxy velocity dispersions and ages. We discuss our findings in the context of galaxy growth scenarios, including minor mergers and progenitor bias, and the possible occurrence of different quenching mechanisms across redshift. With this work, we present the first stellar population gradients from NIRSpec-MSA spectroscopy, in the largest current sample of distant, quiescent galaxies.