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

Abstract

We report the first detection of multiphase gas within a quiescent galaxy beyond z≈0. The observations use the brighter image of doubly lensed QSO HE 0047-1756 to probe the ISM of the massive (M star≈ 1011 M) elliptical lens galaxy at zgal=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 H2 in the lens ISM at projected distance d=4.6 kpc. The H2 column density is N(H2)/cm-2=17.8+0.1-0.3 with a molecular gas fraction of fH2=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(O VI)/cm-2 =15.20.1 and log N(N V)/cm-2 =14.60.1, among the highest known in external galaxies. Assuming the high-ionization absorption features originate in a transient warm (T105\,K) phase undergoing radiative cooling from a hot halo surrounding the galaxy, we infer a mass accretion rate of 0.5-1.5\,M\,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 1048\,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.