Subband occupation in semiconductor-superconductor nanowires

TL;DR

This paper models subband occupation in semiconductor-superconductor nanowires, revealing that surface charge effects increase subband numbers and reduce energy gaps, which challenges the realization of Majorana zero modes and suggests low chemical potential regimes.

Contribution

It provides a self-consistent theoretical analysis of subband occupation considering realistic surface charges, highlighting challenges for Majorana mode realization in nanowires.

Findings

Surface charge densities increase subband occupation.

Many occupied subbands reduce energy separation, hindering Majorana modes.

Local density of states helps identify multi-subband regimes.

Abstract

Subband occupancy (i.e. the number of occupied subbands or energy levels in the semiconductor) is a key physical parameter characterizing the topological properties of superconductor-semiconductor hybrid systems in the context of the search for non-Abelian Majorana zero modes. We theoretically study the subband occupation of semiconductor nanowire devices as function of the applied gate potential, the semiconductor-superconductor (SM-SC) work function difference, and the surface charge density by solving self-consistently the Schr\"{o}dinger-Poisson equations for the conduction electrons of the semiconductor nanowire. Realistic surface charge densities, which are responsible for band bending, are shown to significantly increase the number of occupied subbands, making it difficult or impossible to reach a regime where only a few subbands are occupied. We also show that the energy separation between subbands is significantly reduced in the regime of many occupied subbands, with highly detrimental consequences for the realization and observation of robust Majorana zero modes. As a consequence, the requirements for the realization of robust topological superconductivity and Majorana zero modes should include a low value of the chemical potential, consistent with the occupation of only a few subbands. Finally, we show that the local density of states on the exposed nanowire facets provides a powerful tool for identifying a regime with many occupied subbands and is capable of providing additional critical information regarding the feasibility of Majorana physics in semiconductor-superconductor devices. In our work, we address both InAs/Al and InSb/Al superconductor-nanowire hybrid systems of current experimental interest.