Statistical Mechanics of the Self-gravitating gas with two or more kinds of Particles

Abstract

We study the statistical mechanics of the self-gravitating gas at thermal equilibrium with two kinds of particles. We start from the partition function in the canonical ensemble which we express as a functional integral over the densities of the two kinds of particles for a large number of particles. The system is shown to possess an infinite volume limit when (N1,N2,V)->infty, keeping N1/V1/3 and N2/V1/3 fixed. The saddle point approximation becomes here exact for (N1,N2,V)->infty.It provides a nonlinear differential equation on the particle densities. For the spherically symmetric case, we compute the densities as functions of two dimensionless physical parameters: eta1=G m12 N1/[V1/3 T] and eta2=G m22 N2/[V1/3 T] (where G is Newton's constant, m1 and m2 the masses of the two kinds of particles and T the temperature). According to the values of eta1 and eta2 the system can be either in a gaseous phase or in a highly condensed phase.The gaseous phase is stable for eta1 and eta2 between the origin and their collapse values. The gas is inhomogeneous and the mass M(R) inside a sphere of radius R scales with R as M(R) propto Rd suggesting a fractal structure. The value of d depends in general on eta1 and eta2 except on the critical line for the canonical ensem- ble where it takes the universal value d simeq 1.6 for all values of N1/N2. The equation of state is computed.It is found to be locally a perfect gas equation of state. Thermodynamic functions are computed as functions of eta1 and eta2. They exhibit a square root Riemann sheet with the branch points on the critical canonical line. This treatment is further generalized to the self-gravitating gas with n-types of particles.

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