KROSS: Mapping the Ha emission across the star-formation sequence at z~1

TL;DR

This study uses the KMOS instrument to map H-alpha emission in about 500 star-forming galaxies at z~1, revealing how star formation and metallicity vary across the galaxy population and their relation to the star formation main sequence.

Contribution

It provides the first spatially resolved analysis of star formation and metallicity trends in a large sample of z~1 galaxies, establishing a resolved star formation main sequence and its relation to galaxy properties.

Findings

Star formation surface density correlates with sSFR deviations from the main sequence.

Galaxies above the main sequence tend to have lower metallicities.

A resolved star formation main sequence similar to the integrated one is observed.

Abstract

We present first results from the KMOS Redshift One Spectroscopic Survey (KROSS), an ongoing large kinematical survey of a thousand, z~1 star forming galaxies, with VLT KMOS. Out of the targeted galaxies (~500 so far), we detect and spatially resolve Ha emission in ~90% and 77% of the sample respectively. Based on the integrated Ha flux measurements and the spatially resolved maps we derive a median star formation rate (SFR) of ~7.0 Msun/yr and a median physical size of <r$_{\rm e}$> = 5.1kpc. We combine the inferred SFRs and effective radii measurements to derive the star formation surface densities ({\Sigma}SFR) and present a "resolved" version of the star formation main sequence (MS) that appears to hold at sub-galactic scales, with similar slope and scatter as the one inferred from galaxy integrated properties. Our data also yield a trend between {\Sigma}SFR and {\Delta}(sSFR) (distance from the MS) suggesting that galaxies with higher sSFR are characterised by denser star formation activity. Similarly, we find evidence for an anti-correlation between the gas phase metallicity (Z) and the {\Delta}(sSFR), suggesting a 0.2dex variation in the metal content of galaxies within the MS and significantly lower metallicities for galaxies above it. The origin of the observed trends between {\Sigma}SFR - {\Sigma}(sSFR) and Z - {\Delta}(sSFR) could be driven by an interplay between variations of the gas fraction or the star formation efficiency of the galaxies along and off the MS. To address this, follow-up observations of the our sample that will allow gas mass estimates are necessary.