The temperature of hot gas halos of early-type galaxies

Abstract

Recently, the temperature T and luminosity LX of the hot gas halos of early type galaxies have been derived with unprecedented accuracy from Chandra data, for 30 galaxies covering a wider range of galactic luminosity (and central velocity dispersion sigmac) than before. This work investigates the origin of the observed temperatures, by examining the relationship between them and the galaxy structure, the gas heating due to Type Ia supernovae (SNIa's) and the gravitational potential, and the dynamical status of the gas flow. In galaxies with sigmac<200 km/s, the T's are close to a fiducial average temperature for the gas when in outflow; at 200<sigmac (km/s)<250, the T's are generally lower than this, and unrelated with sigmac, which requires a more complex gas flow status; at larger sigmac, the T's may increase as sigmac2, as expected for infall heating, though heating from SNIa's, independent of sigmac, should be dominant. All observed T's are larger than the virial temperature, by up to ~0.5 keV. This additional heating can be provided in the X-ray brightest galaxies by SNIa's and infall heating, with a SNIa's energy input even lower than in standard assumptions; in the X-ray fainter ones it can be provided by SNIa's, whose energy input would be required close to the full standard value at the largest sigmac. This same energy input, though, would produce temperatures larger than observed at low sigmac, if entirely thermalized. The values of the observed T's increase from outflows to inflows; the gas is relatively hotter in outflows, though, if the T's are rescaled by the virial temperature. For 200<sigmac(km/s)<250, lower LX values tend to correspond to lower T's, which deserves further investigation.