Accretion of a Plasma Vlasov Gas onto a Reissner-Nordström Black Hole

Abstract

We develop a steady-state, spherically symmetric accretion framework for a two-component plasma Vlasov gas in a Reissner-Nordström spacetime under a fixed background electromagnetic field. For charged test particles, the absorption and scattering domains in phase space are rigorously delineated, and closed-form expressions for the critical angular momentum Lc(E,k) and critical impact parameter bc(E,k) are obtained, providing the kinematic basis for accurate phase-space integration. Integral representations of the particle current density, stress-energy tensor, and principal pressures are derived for general electromagnetic coupling k=qQ/(mM). At infinity, all quantities uniformly recover the neutral Vlasov gas results in Schwarzschild spacetime, while at finite radii the electromagnetically attractive (k<0) component is enhanced and the repulsive (k>0) component suppressed. For the two-component plasma, the single-species particle number and energy accretion rates depend only on the asymptotic boundary conditions and k, whereas the total rates require the mixing fractions of each species. This work provides the first complete analytic treatment of charged Vlasov gas accretion in spherical symmetry with explicit absorption-scattering domain partitioning, and clarifies how the electromagnetic interaction regulates accretion efficiency.