Quantifying wave-function overlaps in inhomogeneous Majorana nanowires

TL;DR

This paper investigates the wave-function overlaps of Majorana zero modes in inhomogeneous nanowires, revealing how inhomogeneities affect their resilience and the accuracy of local measurements for estimating their properties.

Contribution

It introduces a spin-resolved wave-function overlap measure to assess Majorana resilience and analyzes their behavior in various inhomogeneous nanowire configurations.

Findings

Pseudo-Majoranas can be as resilient as topological Majoranas.

Local measurements can reasonably estimate overlaps in uniform wires.

Inhomogeneities reduce the accuracy of local estimators but still provide useful information.

Abstract

A key property of Majorana zero modes is their protection against local perturbations. In the standard picture, this protection is guaranteed by a high degree of spatial nonlocality of the Majoranas, namely a suppressed wave-function overlap, in the topological phase. However, a careful characterisation of resilience to local noise goes beyond mere spatial separation, and must also take into account the projection of wave-function spin. By considering the susceptibility of a given zero mode to different local perturbations, we find the relevant forms of spin-resolved wave-function overlaps that measure its resilience. We quantify these overlaps and study their dependence with nanowire parameters in several classes of experimentally relevant configurations. These include nanowires with inhomogeneous depletion and induced pairing, barriers and quantum dots. Smooth inhomogeneities have been shown to produce near-zero modes, so-called pseudo-Majoranas, below the critical Zeeman field in the bulk. Surprisingly, their resilience is found to be comparable or better than that of topological Majoranas in realistic systems. We further study how accurately their overlaps can be estimated using a purely local measurement on one end of the nanowire, accessible through conventional transport experiments. In uniform nanowires this local estimator is remarkably accurate. In inhomogeneous cases it is less accurate but can still provide reasonable estimates for potential inhomogeneities of the order of the superconducting gap. We further analyse the zero mode wave-function structure, spin texture and spectral features associated with each type of inhomogeneity. All our results highlight the strong connection between internal wave-function degrees of freedom, nonlocality and protection in smoothly inhomogeneous nanowires.