Flavor fluctuations in 3-level quantum dots: Generic SU(3)-Kondo fixed point in equilibrium and non-Kondo fixed points in nonequilibrium

Abstract

We study a 3-level quantum dot in the singly occupied cotunneling regime coupled via a generic tunneling matrix to several multi-channel leads in equilibrium or nonequilibrium. We derive an effective model where also each reservoir has three channels labelled by the quark flavors u, d and s with an effective d.o.s. polarized w.r.t. an eight-dimensional F-spin corresponding to the eight generators of SU(3). In equilibrium we perform a standard poor man scaling analysis and show that tunneling via virtual intermediate states induces flavor fluctuations on the dot which become SU(3)-symmetric at a characteristic and exponentially small low-energy scale TK. Using the numerical renormalization group (NRG) we study in detail the linear conductance and confirm the SU(3)-symmetric Kondo fixed point with universal conductance G=2.25 e2/h for various tunneling setups by tuning the level spacings on the dot. In contrast to the equilibrium case, we find in nonequilibrium that the fixed point model is not SU(3)-symmetric but characterized by rotated F-spins for each reservoir with total vanishing sum. At large voltage we analyse the F-spin magnetization and the current in golden rule as function of a magnetic field for the isospin of the up/down quark and the level spacing to the strange quark. As a smoking gun to detect the nonequilibrium fixed point we find that the curve of zero F-spin magnetization has a particular shape on the dot parameters. We propose that our findings can be generalized to the case of quantum dots with an arbitrary number N of levels.