Effect of non-equilibrium term in two-particle correlation function on electron-phonon collision integrals
Abstract
The derivation of kinetic equation for one-particle distribution function F(p,r,t) from BBGKY chain leads to the collision integral expressed in terms of the two-particle correlation function. The latter is in turn expressed by F using Boltzmann's Stosszahlansatz that implies the neglect of initial one-time correlation function g2(p1,p2,r,t) which is non-diagonal in the momentum space. However, it has been established in non-equilibrium case that pair collisions generate the non-diagonal two-particle correlations that give the essential contribution to the current fluctuations of hot electrons. These correlations have been shown giving also a contribution to the collision integrals, i.e., to kinetic properties of nonequilibrium gas. The expression for electron energy loss rate P via phonons is re-derived in detail from this point of view. The order of value of the new term in P in the cases of acoustic- and optical-phonon scattering is evaluated in the electron temperature approximation using the experimental study of hot-electron energy relaxation time in n-InSb at helium temperatures.
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