The Effects of Galaxy Shape and Rotation on the X-ray Haloes of Early-Type Galaxies

Abstract

We present a detailed diagnostic study of the observed temperatures of the hot X-ray coronae of early-type galaxies. By extending the investigation carried out in Pellegrini (2011) with spherical models, we focus on the dependence of the energy budget and temperature of the hot gas on the galaxy structure and internal stellar kinematics. By solving the Jeans equations we construct realistic axisymmetric three-component galaxy models (stars, dark matter halo, central black hole) with different degrees of flattening and rotational support. The kinematical fields are projected along different lines of sight, and the aperture velocity dispersion is computed within a fraction of the circularized effective radius. The model parameters are chosen so that the models resemble real ETGs and lie on the Faber-Jackson and Size-Luminosity relations. For these models we compute T* (the stellar heating contribution to the gas injection temperature) and Tgm (the temperature equivalent of the energy required for the gas escape). In particular, different degrees of thermalisation of the ordered rotational field of the galaxy are considered. We find that T* and Tgm can vary only mildly due to a pure change of shape. Galaxy rotation instead, when not thermalised, can lead to a large decrease of T*; this effect can be larger in flatter galaxies that can be more rotationally supported. Recent temperature measurements Tx, obtained with Chandra, are larger than, but close to, the T* values of the models, and show a possible trend for a lower Tx in flatter and more rotationally supported galaxies; this trend can be explained by the lack of thermalisation of the whole stellar kinetic energy. Flat and rotating galaxies also show lower Lx values, and then a lower gas content, but this is unlikely to be due to the small variation of Tgm found here for them.