Dynamic response of a single-electron transistor in the ac Kondo regime

TL;DR

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Contribution

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Abstract

A single-electron transistor (SET) in a magnetic field irradiated with microwaves is studied theoretically in non-equilibrium Kondo regime. The two fold effect of frequency--\Omega--microwaves is considered as follows: the oscillations in the voltage with frequency \Omega and in the coupling parameters with frequency \Omega/p (p\in\mathbb{N}). We describe the system by the Kondo model at a specific point in the Toulouse limit. A non-perturbative technique is proposed, namely, the non-equilibrium Green's functions and physical observables are averaged over a period of 2\pi p/\Omega. When the microwave irradiation is considered affecting only the voltage, one sees the Kondo satellites as stated in the previous studies. Moreover, the features of the differential conductance and magnetic susceptibility of a SET become richer when the Kondo couplings are considered oscillating on time. We obtain the satellite peak splitting. It explains the possibilities one can find in experimental results that the distance between peaks, which appear in the differential conductance -- magnetic amplitude characteristics G(H) or in the differential conductance -- dc voltage characteristics G(V_{dc}), can be smaller than \hbar\Omega.