First principles calculation of conductance and current flow through low-dimensional superconductors

TL;DR

This paper introduces a new theoretical approach to calculate electrical conductance and current flow in disordered low-dimensional superconductors, incorporating thermal fluctuations, magnetic effects, and vortex excitations.

Contribution

The authors develop an exact current expression and an efficient Monte Carlo algorithm for large systems, enabling detailed analysis of superconducting transport phenomena including phase fluctuations and magnetic field effects.

Findings

Successfully applied to superconductor-normal interfaces and Josephson junctions.

Demonstrated inclusion of decoherence, dephasing, and magnetic fields in the formalism.

Visualized resistance emergence at the superconductor-insulator transition.

Abstract

We present a novel formulation to calculate transport through disordered superconductors connected between two metallic leads. An exact expression for the current is derived, and is applied to a superconducting sample described by the negative-$U$ Hubbard model. A Monte Carlo algorithm that includes thermal phase and amplitude fluctuations of the superconducting order parameter is employed, and a new efficient algorithm is described. This improved routine allows access to relatively large systems, which we demonstrate by applying it to several cases, including superconductor-normal interfaces and Josephson junctions. The effects of decoherence and dephasing are shown to be included in the formulation, which allows the unambiguous characterization of the Kosterlitz-Thouless transition in two-dimensional systems and the calculation of the finite resistance due to vortex excitations in quasi one-dimensional systems. Effects of magnetic fields can be easily included in the formalism, and are demonstrated for the Little-Parks effect in superconducting cylinders. Moreover, the formalism enables us to map the local super and normal currents, and the accompanying electrical potentials, which we use to pinpoint and visualize the emergence of resistance across the superconductor-insulator transition.