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We examine the effects of the electron-electron interaction on the Anderson transition. It is shown that the dimensionality of the system and the range of the interaction are crucial in determining the decay properties of a single-particle citation. For a long-range interaction we find that the appropriate one-electron excitations, when localized, decay via a (-) ^1{d} law where (-) is the energy above the Fermi energy and d is the dimensionality. At finite temperatures this becomes a T^1{d+1} law. The single-particle excitations are bound for short-range forces. The conditions for the persistence of the Anderson transition are presented in terms of the nature of the "m-basis" (that in which the Green's function is diagonal) and the convergence of a series for the renormalized self-energy.
Fleǐshman et al. (Sat,) studied this question.