Integrating all-optical switching with spintronics

TL;DR

This paper demonstrates the integration of single-pulse all-optical magnetic switching with spin Hall effect-driven domain wall motion in Pt/Co/Gd racetracks, advancing the development of fast, energy-efficient photonic spintronic memory devices.

Contribution

It introduces a novel experimental demonstration of combining single-pulse AOS with SHE-driven domain wall motion in synthetic-ferrimagnetic racetracks, enabling integrated photonic memory functionalities.

Findings

Single-pulse AOS achieved in Pt/Co/Gd racetracks.

Efficient SHE-induced domain wall motion demonstrated.

Chirality of written domain walls verified.

Abstract

All-optical switching (AOS) of magnetic materials describes the reversal of the magnetization using short (femtosecond) laser pulses, and has been observed in a variety of materials. In the past decade it received extensive attention due to its high potential for fast and energy-efficient data writing in future spintronic memory applications. Unfortunately, the AOS mechanism in the ferromagnetic multilayers commonly used in spintronics needs multiple pulses for the magnetization reversal, losing its speed and energy efficiency. Here, we experimentally demonstrate `on-the-fly' single-pulse AOS in combination with spin Hall effect (SHE) driven motion of magnetic domains in Pt/Co/Gd synthetic-ferrimagnetic racetracks. Moreover, using field-driven-SHE-assisted domain wall (DW) motion measurements, both the SHE efficiency in the racetrack is determined and the chirality of the optically written DW's is verified. Our experiments demonstrate that Pt/Co/Gd racetracks facilitate both single-pulse AOS as well as efficient SHE induced domain wall motion, which might ultimately pave the way towards integrated photonic memory devices.