Metallization and proximity superconductivity in topological insulator nanowires

TL;DR

This paper investigates how coupling a superconductor to a topological insulator nanowire affects its electronic properties, revealing both challenges and potential benefits for realizing topological superconductivity and Majorana bound states.

Contribution

It provides a detailed analysis of metallization effects in TI nanowires due to superconductor coupling, highlighting how these effects can be mitigated or exploited for topological phases.

Findings

Metallization shifts TI nanowire subbands by ~20 meV.

Coupling induces potential breaking inversion symmetry, lifting spin degeneracy.

Metallization effects can reduce the magnetic field needed for topological phase.

Abstract

A heterostructure consisting of a topological insulator (TI) nanowire brought into proximity with a superconducting layer provides a promising route to achieve topological superconductivity and associated Majorana bound states (MBSs). Here, we study effects caused by such a coupling between a thin layer of an $s$-wave superconductor and a TI nanowire. We show that there is a distinct phenomenology arising from the metallization of states in the TI nanowire by the superconductor. In the strong coupling limit, required to induce a large superconducting pairing potential, we find that metallization results in a shift of the TI nanowire subbands ($\sim 20$ meV) as well as it leads to a small reduction in the size of the subband gap opened by a magnetic field applied parallel to the nanowire axis. Surprisingly, we find that metallization effects in TI nanowires can also be beneficial. Most notably, coupling to the superconductor induces a potential in the portion of the TI nanowire close to the interface with the superconductor, this breaks inversion symmetry and at finite momentum lifts the spin degeneracy of states within a subband. As such coupling to a superconductor can create or enhance the subband splitting that is key to achieving topological superconductivity. This is in stark contrast to semiconductors, where it has been shown that metallization effects always reduce the equivalent subband-splitting caused by spin-orbit coupling. We also find that in certain geometries metallization effects can reduce the critical magnetic required to enter the topological phase. We conclude that, unlike in semiconductors, the metallization effects that occur in TI nanowires can be relatively easily mitigated, for instance by modifying the geometry of the attached superconductor or by compensation of the TI material.