Andreev spectrum and supercurrents in nanowire-based SNS junctions containing Majorana bound states

TL;DR

This paper systematically studies the evolution of Andreev spectra and supercurrents in nanowire-based SNS junctions with Majorana bound states, revealing how topological transitions affect observable properties.

Contribution

It provides a detailed numerical analysis of MBS emergence, hybridization effects, and supercurrent behavior in short and long junctions, including effects of disorder and temperature.

Findings

MBSs cause energy splitting at phase difference π.

Supercurrents show a sawtooth profile in the topological phase.

Long junctions have significant contributions from the quasi-continuum spectrum.

Abstract

Hybrid superconductor-semiconductor nanowires with Rashba spin-orbit coupling are arguably becoming the leading platform for the search of Majorana bound states (MBSs) in engineered topological superconductors. We perform a systematic numerical study of the low-energy Andreev spectrum and supercurrents in short and long superconductor-normal-superconductor junctions made of nanowires with strong Rashba spin-orbit coupling, where an external Zeeman field is applied perpendicular to the spin-orbit axis. In particular, we investigate the detailed evolution of the Andreev bound states from the trivial into the topological phase and their relation with the emergence of MBSs. Due to finite length, the system hosts four MBSs, two at the inner part of the junction and two at the outer one. They hybridize and give rise to a finite energy splitting at superconducting phase difference $\phi=\pi$, a well-visible effect that can be traced back to the evolution of the energy spectrum with the Zeeman field: from the trivial phase with Andreev bound states into the topological phase with MBSs. Similarly, we carry out a detailed study of supercurrents for short and long junctions from the trivial to the topological phases. The supercurrent, calculated from the Andreev spectrum, is $2\pi$-periodic in the trivial and topological phases. In the latter it exhibits a clear \emph{sawtooth} profile at phase difference of $\pi$ when the energy splitting is negligible, signalling a strong dependence of current-phase curves on the length of the superconducting regions. Effects of temperature, scalar disorder and reduction of normal transmission on supercurrents are also discussed. Further, we identify the individual contribution of MBSs. In short junctions the MBSs determine the current-phase curves, while in long junctions the spectrum above the gap (quasi-continuum) introduces an important contribution.