The MOSDEF Survey: A Comprehensive Analysis of the Rest-optical Emission-line Properties of $z\sim 2.3$ Star-forming Galaxies

TL;DR

This study analyzes the emission-line spectra of $z extasciimath{\sim}2.3$ star-forming galaxies, revealing two distinct populations with different ionization properties and physical characteristics, highlighting the importance of these differences in understanding high-redshift galaxy evolution.

Contribution

It introduces a detailed classification of high-redshift galaxies into two populations based on emission-line properties and explores their physical and chemical differences using photoionization models.

Findings

Two galaxy populations with distinct emission-line offsets identified.

High population has higher ionization parameters and is more $ m{ extit{ extalpha}}$-enhanced.

Both populations are more $ m{ extit{ extalpha}}$-enhanced than local galaxies.

Abstract

We analyze the rest-optical emission-line spectra of $z\sim2.3$ star-forming galaxies in the complete MOSFIRE Deep Evolution Field (MOSDEF) survey. In investigating the origin of the well-known offset between the sequences of high-redshift and local galaxies in the [O III]5008/H$\beta$ vs. [N II]6585/H$\alpha$ ("[N II] BPT") diagram, we define two populations of $z\sim2.3$ MOSDEF galaxies. These include the "high" population that is offset towards higher [O III]5008/H$\beta$ and/or [N II]6585/H$\alpha$ with respect to the local SDSS sequence and the "low" population that overlaps the SDSS sequence. These two groups are also segregated within the [O III]5008/H$\beta$ vs. [S II]6718,6733/H$\alpha$ and the [O III]4960,5008/[O II]3727,3730 (O$_{32}$) vs. ([O III]4960,5008+[O II]3727,3730)/H$\beta$ (R$_{23}$) diagram, which suggests qualitatively that star-forming regions in the more offset galaxies are characterized by harder ionizing spectra at fixed nebular oxygen abundance. We also investigate many galaxy properties of the split sample and find that the "high" sample is on average smaller in size and less massive, but has higher specific star-formation rate and star-formation-rate surface density values and is slightly younger compared to the "low" population. From Cloudy+BPASS photoionization models, we estimate that the "high" population has a lower stellar metallicity (i.e., harder ionizing spectrum) but slightly higher nebular metallicity and higher ionization parameter compared to the "low" population. While the "high" population is more $\alpha$-enhanced (i.e., higher $\alpha$/Fe) than the "low" population, both samples are significantly more $\alpha$-enhanced compared to local star-forming galaxies with similar rest-optical line ratios. These differences must be accounted for in all high-redshift star-forming galaxies -- not only those "offset" from local excitation sequences.