Role of bias and tunneling asymmetries in nonlinear Fermi-liquid transport through an SU(N) quantum dot

Abstract

We study how bias and tunneling asymmetries affect nonlinear current through a quantum dot with N discrete levels in the Fermi liquid regime, using an exact low-energy expansion of the current derived up to terms of order V3 with respect to the bias voltage. The expansion coefficients are described in terms of the phase shift, the linear susceptibilities, and the three-body correlation functions, defined with respect to the equilibrium ground state of the Anderson impurity model. In particular, the three-body correlations play an essential role in the order V3 term, and their coupling to the nonlinear current depends crucially on the bias and tunnel asymmetries. The number of independent components of the three-body correlation functions increases with N the internal degrees of the quantum dots, and it gives a variety in the low-energy transport. We calculate the correlation functions over a wide range of electron fillings of the Anderson impurity model with the SU(N) internal symmetry, using the numerical renormalization group. We find that the order V3 nonlinear current through the SU(N) Kondo state, which occurs at electron fillings of 1 and N-1 for strong Coulomb interactions, significantly varies with the three-body contributions as tunnel asymmetries increase. Furthermore, in the valence fluctuation regime toward the empty or fully occupied impurity state, a sharp peak emerges in the coefficient of V3 current in the case at which bias and tunneling asymmetries cooperatively enhance the charge transfer from one of the electrodes.