Spin-Orbit Proximity Effect in Bi/Co Multilayer: The Role of Interface Scattering

TL;DR

This study investigates the spin-orbit proximity effect in Cobalt/Bismuth multilayers, revealing how interface scattering influences magnetic and transport properties, with potential implications for discovering new quantum phases.

Contribution

It provides experimental evidence linking interface scattering to the spin-orbit proximity effect in Bi/Co multilayers, highlighting the role of extrinsic skew-scattering mechanisms.

Findings

Increased magnetic anisotropy at low Co thicknesses.

Anomalous Hall resistivity influenced by interface scattering.

Spin-orbit proximity related to elastic scattering at interfaces.

Abstract

The Spin-Orbit Proximity Effect is the raise of Spin-Orbit Coupling at a layer near to the interface with a strong spin-orbit material. It has been seen in several system such as graphene and ferromagnetic layers. The control of the Spin-Orbit Coupling can be a pathway to discover novel and exotic phases in superconductor and semimetallic systems. Here, we study the magnetoelectrical transport, i.e., magnetoresistance and anomalous Hall effect, in Cobalt/Bismuth multilayers looking for traces of spin-orbit proximity effect and evaluate the origin of such effect. Our results point for an increase of Spontaneous Magnetic Anisotropy of Resistivity and Anomalous Hall Resistivity at very low thicknesses of Cobalt. The analysis of the Anomalous Hall Resisitivity indicate that the Bismuth layers change the scattering mechanism of Hall effect to the extrinsic skew-scattering type, indicating that the spin-orbit proximity effect could be related to the elastic scattering of cobalt free carriers by bismuth sites at the interface.