New Signatures of the Spin Gap in Quantum Point Contacts

Overview

Journal Nat Commun

Specialty Biology

Date 2021 Jan 5

PMID 33397919

Authors

K L Hudson

A Srinivasan

O Goulko

J Adam

Q Wang

L A Yeoh

O Klochan

I Farrer

D A Ritchie

A Ludwig

A D Wieck

J von Delft

A R Hamilton

Affiliations

Soon will be listed here.

Abstract

One dimensional semiconductor systems with strong spin-orbit interaction are both of fundamental interest and have potential applications to topological quantum computing. Applying a magnetic field can open a spin gap, a pre-requisite for Majorana zero modes. The spin gap is predicted to manifest as a field dependent dip on the first 1D conductance plateau. However, disorder and interaction effects make identifying spin gap signatures challenging. Here we study experimentally and numerically the 1D channel in a series of low disorder p-type GaAs quantum point contacts, where spin-orbit and hole-hole interactions are strong. We demonstrate an alternative signature for probing spin gaps, which is insensitive to disorder, based on the linear and non-linear response to the orientation of the applied magnetic field, and extract a spin-orbit gap ΔE ≈ 500 μeV. This approach could enable one-dimensional hole systems to be developed as a scalable and reproducible platform for topological quantum applications.

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