Tuning nanosecond switching of spin-orbit torque driven magnetic tunnel junctions

TL;DR

This paper investigates the mechanisms behind nanosecond switching in spin-orbit torque magnetic tunnel junctions, highlighting the role of current-induced effective fields and external field tuning for optimizing switching speed and symmetry.

Contribution

It provides a detailed analysis of how external fields influence switching symmetry and demonstrates the importance of magnetic configuration manipulation for fast SOT switching.

Findings

Current-induced effective fields are crucial for fast switching.

External field tuning can control switching symmetry.

Magnetic configuration manipulation enhances switching performance.

Abstract

Since the discovery of the spin orbit torque (SOT) induced by spin Hall effect in heavy metals, much effort has been devoted to understanding the mechanism of the charge-to-spin conversion as well as to developing new schemes for high speed, low energy magnetic recording technologies. While fast switching has been demonstrated in three terminal magnetic tunnel junctions (3T-MTJs) through applying short voltage pulses in the heavy metal channel, detailed understanding of the switching mechanism is lacking due to the complexity of the multi-layered magnetic structure and the three-terminal geometry. We show in this letter that current-induced effective fields play a key role in the fast switching and by tuning the applied external field we can finely tune the symmetry of the pulse switching between two switching polarities, namely parallel to anti-parallel (P-AP) and anti-parallel to parallel (AP-P). These results show that the manipulation of detailed magnetic configuration is the key to fast switching and is a useful way for future optimization of SOT memory and further applications.