Kondo effect in systems with dynamical symmetries
Abstract
This paper is devoted to a systematic exposure of the Kondo physics in quantum dots for which the low energy spin excitations consist of a few different spin multiplets |SiMi>. Under certain conditions (to be explained below) some of the lowest energy levels ESi are nearly degenerate. The dot in its ground state cannot then be regarded as a simple quantum top in the sense that beside its spin operator other dot (vector) operators Rn are needed (in order to fully determine its quantum states), which have non-zero matrix elements between states of different spin multiplets <SiMi | Rn|SjMj > 0. These "Runge-Lenz" operators do not appear in the isolated dot-Hamiltonian (so in some sense they are "hidden"). Yet, they are exposed when tunneling between dot and leads is switched on. The effective spin Hamiltonian which couples the metallic electron spin s with the operators of the dot then contains new exchange terms, Jn s · Rn beside the ubiquitous ones Ji s· Si. The operators Si and Rn generate a dynamical group (usually SO(n)). Remarkably, the value of n can be controlled by gate voltages, indicating that abstract concepts such as dynamical symmetry groups are experimentally realizable. Moreover, when an external magnetic field is applied then, under favorable circumstances, the exchange interaction involves solely the Runge-Lenz operators Rn and the corresponding dynamical symmetry group is SU(n). For example, the celebrated group SU(3) is realized in triple quantum dot with four electrons.
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