Distinguishing trivial and topological zero energy states in long nanowire junctions

TL;DR

This paper proposes a simple method to distinguish between trivial and topological zero energy states in long superconductor-normal-superconductor junctions by analyzing the length dependence of supercurrents, aiding in the identification of Majorana bound states.

Contribution

It introduces a protocol based on supercurrent length dependence to differentiate trivial zero energy states from topological Majorana bound states in long junctions.

Findings

Supercurrents are sensitive to superconductor length in topological phase with MBSs.

Trivial zero energy states show no length dependence in supercurrents.

The proposed method effectively distinguishes trivial from topological zero energy states.

Abstract

The emergence of zero energy states in non-topological superconductors represents an inevitable problem that obscures the proper identification of zero energy Majorana bound states (MBSs) and prevents their use as topologically protected qubits. In this Research Letter we investigate long superconductor-normal-superconductor junctions where trivial zero energy states, robust over a large range of parameters, appear as a result of helicity and confinement in the normal region. We demonstrate that both equilibrium supercurrents and critical currents are sensitive to variations in the length of the superconductor regions in the topological phase hosting MBSs, but, remarkably, no such length dependence exists when robust, but trivial, zero energy states are present. This strikingly different response originates from the non-local nature of the MBSs and we, therefore, propose it as a simple protocol for distinguishing between trivial and topological zero energy states.