Full-scale field-free spin-orbit switching of the CoPt layer grown on vicinal substrates

TL;DR

This study demonstrates full-scale, field-free spin-orbit torque switching of CoPt layers grown on vicinal substrates, enabling improved control and efficiency for spintronic device applications.

Contribution

It introduces a novel approach using vicinal substrates to achieve complete, field-free SOT switching in CoPt layers, with tunable magnetic properties and enhanced SOT efficiency.

Findings

Achieved 100% switching ratio in CoPt layers on vicinal substrates.

Tuned magnetic anisotropy and DMI via substrate inclination.

Enhanced SOT efficiency with vicinal substrate growth.

Abstract

A simple, reliable and field-free spin orbit torque (SOT)-induced magnetization switching is a key ingredient for the development of the electrical controllable spintronic devices. Recently, the SOT induced deterministic switching of the CoPt single layer has attracts a lot of interests, as it could simplifies the structure and add new flexibility in the design of SOT devices, compared with the Ferromagnet/Heavy metal bilayer counterparts. Unfortunately, under the field-free switching strategies used nowadays, the switching of the CoPt layer is often partial, which sets a major obstacle for the practical applications. In this study, by growing the CoPt on vicinal substrates, we could achieve the full-scale (100% switching ratio) field-free switching of the CoPt layer. We demonstrate that when grown on vicinal substrates, the magnetic easy axis of the CoPt could be tilted from the normal direction of the film plane; the strength of Dzyaloshinskii Moriya interaction (DMI) would be also be tuned as well. Micromagnetic simulation further reveal that the field-free switching stems from tilted magnetic anisotropy induced by the vicinal substrate, while the enhancement of DMI help reducing the critical switching current. In addition, we also found that the vicinal substrates could also enhance the SOT efficiency. With such simple structure, full-scale switching, tunable DMI and SOT efficiency, our results provide a new knob for the design SOT-MRAM and future spintronic devices.