The Kondo crossover in shot noise of a single quantum dot with orbital degeneracy

Abstract

We investigate out of equilibrium transport through an orbital Kondo system realized in a single quantum dot, described by the multiorbital impurity Anderson model. Shot noise and current are calculated up to the third order in bias voltage in the particle-hole symmetric case, using the renormalized perturbation theory. The derived expressions are asymptotically exact at low energies. The resulting Fano factor of the backscattering current Fb is expressed in terms of the Wilson ratio R and the orbital degeneracy N as Fb =1 + 9(N-1)(R-1)21 + 5(N-1)(R-1)2 at zero temperature. Then, for small Coulomb repulsions U, we calculate the Fano factor exactly up to terms of order U5, and also carry out the numerical renormalization group calculation for intermediate U in the case of two- and four-fold degeneracy (N=2,\,4). As U increases, the charge fluctuation in the dot is suppressed, and the Fano factor varies rapidly from the noninteracting value Fb=1 to the value in the Kondo limit Fb=N+8N+4, near the crossover region U π , with the energy scale of the hybridization .