Bismuth doping induced enhancement of the spin-orbit coupling strength in the prototype dilute ferromagnetic semiconductor (Ga,Mn)As: a review

TL;DR

This review discusses how bismuth doping in (Ga,Mn)As enhances spin-orbit coupling, affecting magnetic and transport properties, with implications for spintronic device applications.

Contribution

It provides a comprehensive overview of how Bi incorporation influences structural, magnetic, and magnetotransport properties in (Ga,Mn)As, highlighting the enhancement of spin-orbit coupling.

Findings

Bi addition increases coercive fields and magnetoresistance.

Bi enhances spin-orbit coupling strength in the valence band.

Magnetotransport effects are significantly improved with Bi doping.

Abstract

Extensive studies on the impact of bismuth incorporation into the (Ga,Mn)As prototype dilute ferromagnetic semiconductor (DFS) on its structural, magnetic and magnetotransport properties are summarized in this review. Thin epitaxial layers of the quaternary (Ga,Mn)(Bi,As) compound, containing up to 1% Bi and 6% Mn atoms, and the reference ternary (Ga,Mn)As compound, have been grown under either a compressive or tensile biaxial misfit strain by the low-temperature molecular-beam epitaxy technique with precisely optimized growth conditions. The high-resolution X-ray diffractometry measurements and transmission electron microscopy imaging of cross-sections across the sample interfaces have evidenced for high structural perfection of the DFS layers and sharp interfaces with the substrate. An addition of bismuth into the layers causes a small decrease in their ferromagnetic Curie temperature and a distinct increase in the coercive fields, as revealed by the superconducting quantum interference device magnetometry investigations. Most of all, the incorporation of a small atomic fraction of heavy Bi atoms, substituting As atoms in the layer, predominantly enhances the spin-orbit coupling strength in its valence band, considerably affecting electromagnetic properties of the layers. Investigations of magnetotransport properties of the DFS layers, performed on micro-Hall-bars prepared from the layers using electron-beam lithography patterning, reveal, as a result of Bi addition to the layers, significantly enhanced magnitudes of magnetoresistance, anomalous and planar Hall effects as well as the spin-orbit torque effect. The latter effect is of special interest for applications to the next generation non-volatile data storage and logic spintronic devices, utilizing electrically controlled magnetization reversal.