Picosecond Spin-Orbit Torque Induced Coherent Magnetization Switching in a Ferromagnet

TL;DR

This study demonstrates ultrafast, coherent spin-orbit torque-induced magnetization switching in a ferromagnet, achieving ~70 ps zero-crossing times and eliminating incubation delays, paving the way for faster magnetic memory devices.

Contribution

It introduces a method to achieve ultrafast, coherent SOT switching without incubation delay by avoiding nucleation, using picosecond current pulses and magneto-optical probing.

Findings

Magnetization zero-crossing occurs in ~70 ps.

Complete switching takes ~250 ps, limited by heat diffusion.

Switching dynamics are coherent with no noticeable incubation delay.

Abstract

Electrically controllable non-volatile magnetic memories show great potential for the replacement of semiconductor-based technologies. Recently there has been strong interest in spin-orbit torque (SOT) induced magnetization reversal due to the device's increased lifetime and speed of operation. However, recent SOT switching studies reveal an incubation delay in the ~ns range due to stochasticity in the nucleation of a magnetic domain during reversal. Here, we experimentally demonstrate ultrafast SOT-induced magnetization switching dynamics of a ferromagnet with no incubation delay by avoiding the nucleation process and driving the magnetization coherently. We employ an ultrafast photo-conducting switch and a co-planar strip line to generate and guide ~ps current pulses into the heavy metal/ferromagnet layer stack and induce ultrafast SOT. We use magneto-optical probing to investigate the magnetization switching dynamics with sub-picosecond time resolution. Depending on the relative current pulse and in-plane magnetic field polarities, we observe either an ultrafast demagnetization and subsequent recovery along with a SOT-induced precessional oscillation, or ultrafast SOT switching. The magnetization zero-crossing occurs in ~70 ps, which is approximately an order of magnitude faster than previous studies. Complete switching needs ~250 ps and is limited by the heat diffusion to the substrate. We use a macro-magnetic simulation coupled with an ultrafast heating model to analyze the effect of ultrafast thermal anisotropy torque and current-induced torque in the observed dynamics. Good agreement between our experimental results and the macro-spin model shows that the switching dynamics are coherent and present no noticeable incubation delay. Our work suggests a potential pathway toward dramatically increasing the writing speed of SOT magnetic random-access memory devices.