The MOSDEF Survey: Broad Emission Lines at z=1.4-3.8

TL;DR

This study analyzes broad emission lines in star-forming galaxies at redshifts 1.4 to 3.8, revealing their properties, potential origins like shocks or AGN, and their relation to galaxy mass and evolution.

Contribution

It provides the first detailed decomposition of broad and narrow emission components in high-redshift galaxies, exploring their origins and implications for galaxy outflows and evolution.

Findings

Broad emission detected in less than 10% of galaxies.

Broad flux accounts for 10-70% of total emission.

Mass loading factor increases with galaxy mass.

Abstract

We present results from the MOSFIRE Deep Evolution Field (MOSDEF) survey on broad flux from the nebular emission lines H$\alpha$, [NII], [OIII], H$\beta$, and [SII]. The sample consists of 127 star-forming galaxies at $1.37 < z < 2.61$ and 84 galaxies at $2.95 < z < 3.80$. We decompose the emission lines using narrow ($\text{FWHM} < 275 \ \text{km s}^{-1}$) and broad ($\text{FWHM} > 300 \ \text{km s}^{-1}$) Gaussian components for individual galaxies and stacks. Broad emission is detected at $>3\sigma$ in $<10$% of galaxies and the broad flux accounts for 10-70% of the total flux. We find a slight increase in broad to narrow flux ratio with mass but note that we cannot reliably detect broad emission with $\text{FWHM} < 275 \ \text{km s}^{-1}$, which may be significant at low masses. Notably, there is a correlation between higher signal-to-noise (S/N) spectra and a broad component detection indicating a S/N dependence in our ability to detect broad flux. When placed on the N2-BPT diagram ([OIII]/H$\beta$ vs. [NII]/H$\alpha$) the broad components of the stacks are shifted towards higher [OIII]/H$\beta$ and [NII]/$\alpha$ ratios compared to the narrow component. We compare the location of the broad components to shock models and find that the broad component could be due to shocks, but we do not rule out other possibilities such as the presence of an AGN. We estimate the mass loading factor (mass outflow rate/star formation rate) assuming the broad component is a photoionized outflow and find that the mass loading factor increases as a function of mass which agrees with previous studies. We show that adding emission from shocked gas to $z\sim0$ SDSS spectra shifts galaxies towards the location of $z\sim2$ galaxies on several emission line diagnostic diagrams.