Stability of rigidly rotating supermassive stars against gravitational collapse

Abstract

We revisit secular stability against quasi-radial collapse for rigidly rotating supermassive stars (SMSs) in general relativity. We suppose that the SMSs are in a nuclear-burning phase and can be modeled by polytropic equations of state with the polytropic index np slightly smaller than 3. The stability is determined in terms of the turning-point method. We find a fitting formula of the stability condition for the plausible range of np (2.95 np 3) for SMSs. This condition reconfirms that, while non-rotating SMSs with mass 105M--106M may undergo a general-relativistically induced quasi-radial collapse, rigidly rotating SMSs with a ratio of rotational to gravitational potential energy (β) of 10-2 are likely to be stable against collapse unless they are able to accrete 5 times more mass during the (relatively brief) hydrogen-burning phase of their evolution. We discuss implications of our results.