Linear response theory of electrical conductivity of a plasma and improvements of the Lenard-Balescu equation

The plasma convolution equation equivalent to the initial problem of linearized BOLTZ-~&~"-VLASOV and POISSON'S equations of an htropic, one-dimensional and nonrelativistic plasma is derived. The integd equation obtained involves both the time t and space coordinate x. The solution of this equation

## Abstract The electrical conductivity of a nonideal hydrogen plasma is calculated within the linear response formalism. The approximation given involves the first term with respect to the density expansion in the low degenerate case. The contributions of the free‐free scattering of the particles

The longitudinal and transverse conductivities of the disordered system of charge particles is considered. The linear response theory with respect to weak external field and the perturbation theory for the interaction between the particles and photons are investigated. The expressions for conducti

## Abstract The electrical conductivity of polymeric materials can be increased by the addition of carbon fillers. The resulting composites can be used in applications such as electrostatic dissipation and interference shielding. Electrical conductivity models are often proposed to predict the cond

## Abstract The partially ionized plasma is described by a model Hamiltonian containing bound (localized) as well as orthogonalized free (itinerant) electron states. The equations of balance for the single particle states are given, and the correlation functions arising in the equations of balance