The Non-collinear Path to Topological Superconductivity

TL;DR

This paper reports the experimental discovery of topological superconductivity in a non-collinear spin texture system, specifically Fe/Ta(110), revealing edge modes with magnetization-dependent dispersion and signatures of Rashba spin-orbit coupling.

Contribution

It demonstrates topological superconductivity in a non-collinear spin texture system, expanding the understanding beyond collinear magnetic systems.

Findings

Topological nodal-point superconducting phase identified

Edge modes exhibit magnetization-dependent dispersion

Signatures of Rashba spin-orbit coupling observed

Abstract

Combining spin textures in ultra-thin films with conventional superconductors has emerged as a powerful and versatile platform for designing topologically non-trivial superconducting phases as well as spin-triplet Cooper pairs. As a consequence, two-dimensional magnet-superconductor hybrids (2D MSHs) are promising candidate systems to realize devices for topology-based quantum technologies and superconducting spintronics. So far, studies have focused mostly on systems hosting collinear ferromagnets or antiferromagnets. However, topologically non-trivial phases have been predicted to emerge in MSH systems with non-collinear spin textures as well. In this article, we present the experimental discovery of topological superconductivity in the MSH system Fe/Ta(110) where a magnetic spiral is realized in the Fe monolayer on the surface of the s-wave superconductor Ta. By combining low-temperature spin-polarized scanning tunneling microscopy measurements with theoretical modeling, we are able to conclude that the system is in a topological nodal-point superconducting phase with low-energy edge modes. Due to the non-collinear spin texture in our MSH system, these edge modes exhibit a magnetization direction-dependent dispersion. Furthermore, we identify direct signatures of Rashba spin-orbit coupling in the experimentally measured differential tunneling conductance. The present work realizes a non-collinear spin texture-based path to topological superconductivity.