A thermally driven out-of-equilibrium two-impurity Kondo system

Abstract

The archetypal two-impurity Kondo problem in a serially-coupled double quantum dot is investigated in the presence of a thermal bias θ. The slave-boson formulation is employed to obtain the nonlinear thermal and thermoelectrical responses. When the Kondo correlations prevail over the antiferromagnetic coupling J between dot spins we demonstrate that the setup shows negative differential thermal conductance regions behaving as a thermal diode. Besides, we report a sign reversal of the thermoelectric current I(θ) controlled by t/ (t and denote the interdot tunnel and reservoir-dot tunnel couplings, respectively) and θ. All these features are attributed to the fact that at large θ, both Q(θ) (heat current) and I(θ) are suppressed regardless the value of t/ because the double dot decouples at high thermal biases. Eventually, and for a finite J, we investigate how the Kondo-to-antiferromagnetic crossover is altered by θ.