Enhanced Two-Channel Kondo Physics in a Quantum Box Device

TL;DR

This paper proposes a quantum device design where strong electron correlations enable observable two-channel Kondo effects through enhanced Kondo temperature and clear scaling behavior, facilitating experimental access.

Contribution

It introduces a novel quantum box device with correlated electrons that exhibits robust two-channel Kondo physics, unperturbed by one-dimensional electron correlations.

Findings

Enhanced Kondo temperature due to electron correlations.

Manifest two-channel Kondo scaling in differential capacitance.

Feasibility of experimental realization of the Kondo regime.

Abstract

We propose a design for a one-dimensional quantum box device where the charge fluctuations are described by an anisotropic two-channel Kondo model. The device consists of a quantum box in the Coulomb blockade regime, weakly coupled to a quantum wire by a single-mode point contact. The electron correlations in the wire produce strong back scattering at the contact, significantly increasing the Kondo temperature as compared to the case of non-interacting electrons. By employing boundary conformal field theory techniques we show that the differential capacitance of the box exhibits manifest two-channel Kondo scaling with temperature and gate voltage, uncontaminated by the one-dimensional electron correlations. We discuss the prospect to experimentally access the Kondo regime with this type of device.