Large-Amplitude, Easy-Plane Spin-Orbit Torque Oscillators Driven by Out-of-Plane Spin Current: A Micromagnetic Study

TL;DR

This paper presents a micromagnetic study of a novel spin-orbit torque oscillator that achieves large-amplitude, easy-plane precession with high thermal stability and no external magnetic field, using out-of-plane spin currents.

Contribution

It introduces a new spin torque oscillator design utilizing out-of-plane spin currents to overcome limitations of traditional devices, demonstrated through micromagnetic simulations.

Findings

Achieves large cone angle precession with high thermal stability.

Operates without external bias magnetic field.

Feasible at room temperature across various parameters.

Abstract

Spin torque oscillators are spintronic devices that generate a periodic output signal from a non-periodic input, making them promising candidates for applications like microwave communications and neuromorphic computing. However, traditional spin torque oscillators suffer from a limited precessional cone angle and thermal stability, as well as a need for an applied bias magnetic field. We use micromagnetic simulations to demonstrate a novel spin torque oscillator that relies on spin-orbit effects in ferromagnets to overcome these limitations. The key mechanism behind this oscillator is the generation of an out-of-plane spin current, in which both the spin flow and the spin orientation are out-of-plane. The torque from this spin current enables easy-plane coherent magnetic precession with a large cone angle and high thermal stability over a micron-scale lateral area. Moreover, the precession occurs about an internal field in the free layer, thereby eliminating the need for an external bias field. We demonstrate the feasibility of an easy-plane spin-orbit torque oscillator at room temperature over a wide parameter space, including the ratio of the out-of-plane spin current to the conventional spin-Hall spin current, presenting exciting possibilities for this novel spintronic device.