The Galaxy-Halo Connection for $1.5\lesssim z\lesssim5$ as revealed by the \emph{Spitzer} Matching survey of the UltraVISTA ultra-deep Stripes

TL;DR

This study uses deep Spitzer data to connect galaxy stellar mass to dark matter halos between redshifts 1.5 and 5, revealing how galaxy clustering and halo properties evolve over cosmic time.

Contribution

It introduces a novel method to interpret galaxy clustering with photometric redshift uncertainties and estimates the halo mass where stellar-to-halo mass ratio peaks at high redshift.

Findings

Satellite fraction decreases with redshift.

Clustering amplitude shows monotonic trends with redshift and stellar mass.

Peak halo mass for stellar-to-halo mass ratio is around 10^12.5 M_sun at z~2.5.

Abstract

The \emph{Spitzer} Matching Survey of the UltraVISTA ultra-deep Stripes (SMUVS) provides unparalleled depth at $3.6$ and $4.5$~$\mu$m over $\sim0.66$~deg$^2$ of the COSMOS field, allowing precise photometric determinations of redshift and stellar mass. From this unique dataset we can connect galaxy samples, selected by stellar mass, to their host dark matter halos for $1.5<z<5.0$, filling in a large hitherto unexplored region of the parameter space. To interpret the observed galaxy clustering we utilize a phenomenological halo model, combined with a novel method to account for uncertainties arising from the use of photometric redshifts. We find that the satellite fraction decreases with increasing redshift and that the clustering amplitude (e.g., comoving correlation length / large-scale bias) displays monotonic trends with redshift and stellar mass. Applying $\Lambda$CDM halo mass accretion histories and cumulative abundance arguments for the evolution of stellar mass content we propose pathways for the coevolution of dark matter and stellar mass assembly. Additionally, we are able to estimate that the halo mass at which the ratio of stellar to halo mass is maximized is $10^{12.5_{-0.08}^{+0.10}}$~M$_{\odot}$ at $z\sim2.5$. This peak halo mass is here inferred for the first time from stellar mass-selected clustering measurements at $z\gtrsim2$, and implies mild evolution of this quantity for $z\lesssim3$, consistent with constraints from abundance-matching techniques.