Klaus Morawetz

TL;DR: A generalized kinetic equation describing correlation effects in a consistent approach to nonequilibrium for Bose and Fermi systems is established, which gives a generalization of the Beth-Uhlenbeck formula that applies toNonequilibrium and to finite systems.

TL;DR: Both concepts, cluster decomposition and memory, are compared and it is found that they lead to the same quantum virial corrections of Beth-Uhlenbeck type in equilibrium, however, memory in the kinetic equation causes an additional renormalization of the effective energy transfer in nonequilibrium.

TL;DR: In this article, the effect of collisions is represented by correlation functions which are possible to calculate with the help of the finite temperature Lindhard random-phase approximation expression, which is applicable to the finite-temperature response of interacting quantum systems if the quasiparticle or mean-field energy is parametrized within Skyrme-type functionals including density, current and energy dependencies which can be considered alternatively as density functionals.

TL;DR: Exact cancellation of the two integrals is found if the initial state is thermal equilibrium, which is an important consistency criterion, and results are given for the time evolution of the correlation energy.