General Proof of the Tolman law

Abstract

Tolman proposed that the proper temper T of a static self-gravitating fluid in thermodynamic equilibrium satisfies the relation T=constant, where is the redshift factor of the spacetime. The Tolman law has been proven for radiation in stationary spacetimes and for perfect fluids in stationary, asymototically flat and axisymmetric spacetimes. It is unclear whether the proof can be extended to more general cases. In this paper, we prove that under some reasonable conditions, the Tolman law always holds for a perfect fluid in a stationary spacetime. The key assumption in our proof is that the particle number density n can not be determined by the energy density and pressure p via the equations of state. This is true for many known fluids with the equation of state p=p(). Then, by requiring that the total entropy of the fluid is an extremum for the variation of n with a fixed metric, we prove the Tolman law. In our proof, only the conservations of stress energy and the total particle number are used, and no field equations are involved. Our work suggests that the Tolman law holds for a generic perfect fluid in a stationary spacetime, even beyond general relativity.