Evidence for Late-Time Feedback from the Discovery of Multiphase Gas in a Massive Elliptical at $z=0.4$

TL;DR

This study detects multiphase gas in a massive elliptical galaxy at redshift 0.4, revealing evidence of ongoing late-time feedback processes that regulate cold gas accumulation and galaxy evolution.

Contribution

It provides the first evidence of multiphase gas in a quiescent galaxy beyond redshift 0, indicating ongoing feedback mechanisms from evolved stellar populations.

Findings

Detection of H2 and high-ionization species in the galaxy ISM.

Estimation of mass accretion rate from warm gas cooling.

Implication of stellar feedback preventing cold gas buildup.

Abstract

We report the first detection of multiphase gas within a quiescent galaxy beyond $z\approx0$. The observations use the brighter image of doubly lensed QSO HE 0047$-$1756 to probe the ISM of the massive ($M_{\rm star}\approx 10^{11} \mathrm{M_\odot}$) elliptical lens galaxy at $z_\mathrm{gal}=0.408$. Using Hubble Space Telescope's Cosmic Origins Spectrograph (COS), we obtain a medium-resolution FUV spectrum of the lensed QSO and identify numerous absorption features from $\mathrm{H_2}$ in the lens ISM at projected distance $d=4.6$ kpc. The $\mathrm{H_2}$ column density is $\log N(\mathrm{H_2})/\mathrm{cm^{-2}}=17.8^{+0.1}_{-0.3}$ with a molecular gas fraction of $f_\mathrm{H_2}=2-5\%$, roughly consistent with some local quiescent galaxies. The new COS spectrum also reveals kinematically complex absorption features from highly ionized species O VI and N V with column densities log $N(\mathrm{O VI})/\mathrm{cm^{-2}} =15.2\pm0.1$ and log $N(\mathrm{N V})/\mathrm{cm^{-2}} =14.6\pm0.1$, among the highest known in external galaxies. Assuming the high-ionization absorption features originate in a transient warm ($T\sim10^5\,$K) phase undergoing radiative cooling from a hot halo surrounding the galaxy, we infer a mass accretion rate of $\sim 0.5-1.5\,\mathrm{M_\odot\,yr^{-1}}$. The lack of star formation in the lens suggests the bulk of this flow is returned to the hot halo, implying a heating rate of $\sim10^{48}\,\mathrm{erg\,yr^{-1}}$. Continuous heating from evolved stellar populations (primarily SNe Ia but also winds from AGB stars) may suffice to prevent a large accumulation of cold gas in the ISM, even in the absence of strong feedback from an active nucleus.