A relationship between specific star formation rate and metallicity gradient within z=1 galaxies from KMOS-HiZELS

TL;DR

This study reveals a correlation between specific star formation rate and metallicity gradients in z=1 galaxies, suggesting metal-poor gas inflow influences star formation and galaxy evolution.

Contribution

First to analyze the relationship between sSFR and metallicity gradients in z=1 galaxies using KMOS, clarifying discrepancies in high-redshift metallicity studies.

Findings

High sSFR galaxies tend to have metal-poor centers.

Merging and gas accretion influence metallicity gradients.

Results support the fundamental metallicity relation.

Abstract

We have observed a sample of typical z=1 star forming galaxies, selected from the HiZELS survey, with the new KMOS near-infrared, multi-IFU instrument on the VLT, in order to obtain their dynamics and metallicity gradients. The majority of our galaxies have a metallicity gradient consistent with being flat or negative (i.e. higher metallicity cores than outskirts). Intriguingly, we find a trend between metallicity gradient and specific star formation rate (sSFR), such that galaxies with a high sSFR tend to have relatively metal-poor centres, a result which is strengthened when combined with datasets from the literature. This result appears to explain the discrepancies reported between different high redshift studies and varying claims for evolution. From a galaxy evolution perspective, the trend we see would mean that a galaxy's sSFR is governed by the amount of metal poor gas that can be funnelled into its core, triggered either by merging or through efficient accretion. In fact merging may play a significant role as it is the starburst galaxies at all epochs, which have the more positive metallicity gradients. Our results may help to explain the origin of the fundamental metallicity relation, in which galaxies at a fixed mass are observed to have lower metallicities at higher star formation rates, especially if the metallicity is measured in an aperture encompassing only the central regions of the galaxy. Finally, we note that this study demonstrates the power of KMOS as an efficient instrument for large scale resolved galaxy surveys.