Fast Outflows in Hot Dust-Obscured Galaxies with Keck/NIRES

TL;DR

This study presents spectroscopic evidence of massive ionized outflows and high star formation rates in Hot Dust-Obscured Galaxies, indicating they are a transitional phase in galaxy evolution with active black hole growth.

Contribution

First detailed optical spectroscopic analysis of Hot DOGs revealing massive outflows, high star formation, and black hole properties, highlighting their role in galaxy evolution.

Findings

Most Hot DOGs exhibit broad, blueshifted [O III] emission lines indicating powerful outflows.

Star formation rates are high, with some estimates exceeding 1000 solar masses per year.

Many Hot DOGs host actively accreting black holes near or above their Eddington limit.

Abstract

We present rest-frame optical spectroscopic observations of 24 Hot Dust-Obscured Galaxies (Hot DOGs) at redshifts 1.7-4.6 with KECK/NIRES. Our targets are selected based on their extreme red colors to be the highest luminosity sources from the WISE infrared survey. In 20 sources with well-detected emission we fit the key [O III], H$\beta$, H$\alpha$, [N II], and [S II] diagnostic lines to constrain physical conditions. Of the 17 targets with a clear detection of the [O III]$\rm \lambda$5007A emission line, 15 display broad blueshifted and asymmetric line profiles, with widths ranging from 1000 to 8000 $\rm km\ s^{-1}$ and blueshifts up to 3000 $\rm km\ s^{-1}$. These kinematics provide strong evidence for the presence of massive ionized outflows of up to $8000\ \rm M_\odot\ yr^{-1}$, with a median of $150\ \rm M_\odot\ yr^{-1}$. As many as eight sources show optical emission line ratios consistent with vigorous star formation. Balmer line star-formation rates, uncorrected for reddening, range from 30--1300 $\rm M_\odot\ yr^{-1}$, with a median of $50\ \rm M_\odot\ yr^{-1}$. Estimates of the SFR from SED fitting of mid and far-infrared photometry suggest significantly higher values. We estimate the central black hole masses to be of order $10^{8-10}\rm\ M_\odot$, assuming the present-day $\rm M_{BH}-\sigma_*$ relation. The bolometric luminosities and the estimated masses of the central black holes of these galaxies suggest that many of the AGN-dominated Hot DOGs are accreting at or above their Eddington limit. The combination of ongoing star formation, massive outflows, and high Eddington ratios suggest Hot DOGs are a transitional phase in galaxy evolution.