Statistical mechanics of self-gravitating systems in general relativity: II. The classical Boltzmann gas

Abstract

We study the statistical mechanics of classical self-gravitating systems confined within a box of radius R in general relativity. It has been found that the caloric curve T∞(E) has the form of a double spiral whose shape depends on the compactness parameter =GNm/Rc2. The double spiral shrinks as increases and finally disappears when max=0.1764. Therefore, general relativistic effects render the system more unstable. On the other hand, the cold spiral and the hot spiral move away from each other as decreases. Using a normalization =-ER/GN2m2 and η=GNm2/R kB T∞ appropriate to the nonrelativistic limit, and considering → 0, the hot spiral goes to infinity and the caloric curve tends towards a limit curve (determined by the Emden equation) exhibiting a single cold spiral, as found in former works. Using another normalization M=GM/Rc2 and B=Rc4/GNkB T∞ appropriate to the ultrarelativistic limit, and considering → 0, the cold spiral goes to infinity and the caloric curve tends towards a limit curve (determined by the general relativistic Emden equation) exhibiting a single hot spiral. This result is new. We discuss the analogies and the differences between this asymptotic caloric curve and the caloric curve of the self-gravitating black-body radiation. Finally, we compare box-confined isothermal models with heavily truncated isothermal distributions in Newtonian gravity and general relativity.