Stability of Majorana Fermions in Proximity-Coupled Topological Insulator Nanowires

TL;DR

This paper investigates the robustness of Majorana fermions in topological insulator nanowires coupled to superconductors, showing they remain stable under various realistic perturbations such as chemical potential variations, magnetic flux deviations, and disorder.

Contribution

It provides a comprehensive analysis of the stability of Majorana fermions in realistic conditions, extending previous idealized models to more practical scenarios.

Findings

Majorana fermions persist for any chemical potential within the bulk gap.

They remain stable even with magnetic flux deviations from half flux quantum.

Majorana fermions are robust against strong disorder and potential fluctuations.

Abstract

It has been shown previously that a finite-length topological insulator nanowire, proximity-coupled to an ordinary bulk s-wave superconductor and subject to a longitudinal applied magnetic field, realizes a one-dimensional topological superconductor with an unpaired Majorana fermion (MF) localized at each end of the nanowire. Here, we study the stability of these MFs with respect to various perturbations that are likely to occur in a physical realization of the proposed device. We show that the unpaired Majorana fermions persist in this system for any value of the chemical potential inside the bulk band gap of order 300 meV in Bi$_2$Se$_3$ by computing the Majorana number. From this calculation, we also show that the unpaired Majorana fermions persist when the magnetic flux through the nanowire cross-section deviates significantly from half flux quantum. Lastly, we demonstrate that the unpaired Majorana fermions persist in strongly disordered wires with fluctuations in the on-site potential ranging in magnitude up to several times the size of the bulk band gap. These results suggest this solid-state system should exhibit unpaired Majorana fermions under accessible conditions likely important for experimental study or future applications.