The Shape and Scatter of The Galaxy Main Sequence for Massive Galaxies at Cosmic Noon

TL;DR

This study analyzes the galaxy main sequence for massive galaxies at cosmic noon, revealing its shape, scatter, and evolution without assuming a fixed functional form, providing new insights into galaxy evolution.

Contribution

It introduces a novel, assumption-free method to measure the galaxy main sequence and its scatter across different masses and redshifts.

Findings

The main sequence becomes flatter at high masses towards present day.

The scatter around the main sequence is approximately 0.5-1.0 dex with little evolution.

The increasing fraction of green valley and quiescent galaxies affects the main sequence shape.

Abstract

We present the main sequence for all galaxies and star-forming galaxies for a sample of 28,469 massive ($M_\star \ge 10^{11}$M$_\odot$) galaxies at cosmic noon ($1.5 < z < 3.0$), uniformly selected from a 17.5 deg$^2$ area (0.33 Gpc$^3$ comoving volume at these redshifts). Our large sample allows for a novel approach to investigating the galaxy main sequence that has not been accessible to previous studies. We measure the main sequence in small mass bins in the SFR-M$_{\star}$ plane without assuming a functional form for the main sequence. With a large sample of galaxies in each mass bin, we isolate star-forming galaxies by locating the transition between the star-forming and green valley populations in the SFR-M$_{\star}$ plane. This approach eliminates the need for arbitrarily defined fixed cutoffs when isolating the star-forming galaxy population, which often biases measurements of the scatter around the star-forming galaxy main sequence. We find that the main sequence for all galaxies becomes increasingly flat towards present day at the high-mass end, while the star-forming galaxy main sequence does not. We attribute this difference to the increasing fraction of the collective green valley and quiescent galaxy population from $z=3.0$ to $z=1.5$. Additionally, we measure the total scatter around the star-forming galaxy main sequence and find that it is $\sim0.5-1.0$ dex with little evolution as a function of mass or redshift. We discuss the implications that these results have for pinpointing the physical processes driving massive galaxy evolution.