Microscopic Calculation of the Dielectric Susceptibility Tensor for Coulomb Fluids II
arXiv:cond-mat/0308304 · doi:10.1023/B:JOSS.0000013972.61656.65
Abstract
For a Coulomb system contained in a domain Î, the dielectric susceptibility tensor Ï_Î is defined as relating the average polarization in the system to a constant applied electric field, in the linear limit. According to the phenomenological laws of macroscopic electrostatics, Ï_Î depends on the specific shape of the domain Î. In this paper we derive, using the methods of equilibrium statistical mechanics in both canonical and grand-canonical ensembles, the shape dependence of Ï_Î and the corresponding finite-size corrections to the thermodynamic limit, for a class of general ν-dimensional (ν\ge 2) Coulomb systems, of ellipsoidal shape, being in the conducting state. The microscopic derivation is based on a general principle: the total force acting on a system in thermal equilibrium is zero. The results are checked in the Debye-Hückel limit. The paper is a generalization of a previous one [L. Å amaj, J. Stat. Phys. 100:949 (2000)], dealing with the special case of a one-component plasma in two dimensions. In that case, the validity of the presented formalism has already been verified at the exactly solvable (dimensionless) coupling Î= 2.
22 pages