Inverse Spin Hall Effect Induced by Asymmetric Illumination of Light on Topological Insulator Bi$_2$Se$_3$

TL;DR

This paper demonstrates that asymmetric illumination with circularly polarized light on Bi₂Se₃ topological insulators induces an inverse spin Hall effect, enabling spin injection and manipulation for spintronic applications.

Contribution

It introduces a novel method of spin injection using asymmetric light illumination and models the resulting inverse spin Hall effect with experimental and FEM simulation data.

Findings

Helicity-dependent photocurrent observed at sample edges.

Model predicts electric dipole formation at edges due to ISHE.

Asymmetric light illumination effectively manipulates spin currents.

Abstract

Using circularly polarized light is an alternative to electronic ways for spin injection into materials. Spins are injected at a point of the light illumination, and then diffuse and spread radially due to the in-plane gradient of the spin density. This diffusion is converted into a circular charge current by the inverse spin Hall effect (ISHE). With shining the circularly polarized light at asymmetric parts of the sample, such as near edges, we detected this current as a helicity-dependent component in the photocurrent. We present a model for this ISHE based on the experimental results and the finite-element-method (FEM) simulation of the potential distribution induced by spin injection. Our model shows that the ISHE photocurrent generates an electric dipole at the edge of the sample, causing the measured charge current. The asymmetric light-illumination shown here is a simple way to inject and manipulate spins, opening up a door for novel spintronic devices.