The MOSDEF Survey: Stellar Continuum Spectra and Star Formation Histories of Active, Transitional, and Quiescent Galaxies at 1.4$<$\lowercase{z}$<$2.6

TL;DR

This study uses the MOSDEF survey to analyze the star-formation histories of galaxies at redshifts 1.4 to 2.6, revealing rapid star formation timescales in quiescent and transitional galaxies, contrasting with lower-redshift galaxies.

Contribution

It provides new constraints on the star-formation histories of high-redshift galaxies using stellar continuum spectroscopy and spectral stacking techniques.

Findings

Quiescent and transitional galaxies have short star-formation timescales (~0.1-0.2 Gyr).

High-redshift galaxies form stars over shorter periods than low-redshift counterparts.

Spectral indices correlate with mass surface density across galaxy types.

Abstract

Using the MOSDEF rest-frame optical spectroscopic survey, we investigate the star-formation histories (SFHs) of different galaxy types, ranging from actively star forming to quiescent at $1.4\leq~z\leq2.6$. SFHs are constrained utilizing stellar continuum spectroscopy, specifically through a combination of Balmer absorption lines, the 4000$\AA$ break, and the equivalent width of the H$\alpha$ emission line. To attain a sufficiently high signal-to-noise ratio (S/N) to conduct these measurements we stack spectra of galaxies with similar spectral types, as determined from their rest-frame $U-V$ and $V-J$ colors. We bin the MOSDEF sample into five spectral types, subdividing the quiescent and star-forming bins to better explore galaxies transitioning between the two. We constrain the average SFHs for each type, finding that quiescent and transitional galaxies in the MOSDEF sample are dominated by an SFH with an average star-formation timescale of $\tau\sim0.1-0.2$~Gyr. These findings contrast with measurements from the low-redshift Universe where, on average, galaxies form their stars over a more extended time period ($\tau>1$~Gyr). Furthermore, our spectral index measurements correlate with mass surface density for all spectral types. Finally, we compare the average properties of the galaxies in our transitional bins to investigate possible paths to quiescence, and speculate on the viability of a dusty post-starburst phase.