Josephson diode based on conventional superconductors and a chiral quantum dot

TL;DR

This paper theoretically proposes a Josephson diode using conventional superconductors and a chiral quantum dot, demonstrating controllable nonreciprocal critical currents influenced by magnetic fields and quantum dot parameters.

Contribution

It introduces a novel Josephson diode design with tunable nonreciprocity based on chiral quantum dots and magnetic fields, expanding possibilities for dissipationless diode devices.

Findings

Strong nonreciprocity achievable over large parameter space

Nonreciprocity can be switched on/off by magnetic field direction

Nonreciprocal behavior depends on hopping amplitude, magnetic field, and quantum dot energy level

Abstract

We propose theoretically a Josephson diode consisting of the conventional superconductors with the plain s-wave pairing and a chiral quantum dot. When an external magnetic field is exerted on the quantum dot, the critical current of the Josephson structure is different for the opposite directions of current flow. The strong nonreciprocity can be obtained in a large area of the parameter space. The inversion and the on/off state of the nonreciprocity can be conveniently regulated by adjusting the direction of the external field. The dependences of the nonreciprocal behaviors on the the hopping amplitude, the magnitude of the magnetic field and the energy level of the quantum dot are investigated in details using the Keldysh nonequilibrium Green's function formalism under the self-consistent procedure. The symmetric and the antisymmetric properties of the nonreciprocity are analyzed from symmetries satisfied by the superconductors. The proposed diode effect also applies to other chiral conductors as interlayer. Its formation has no restriction on the type of the current-phase difference relations. The generality and flexibility of our proposed diode effect provides more possibilities for the design of the dissipationless diode devices.