Spin-orbit-torque MRAM: from uniaxial to unidirectional switching

TL;DR

This paper demonstrates a novel spin-orbit torque switching method in MRAM that uses current pulses to control exchange bias, enhancing thermal stability and enabling zero-field unidirectional switching for more reliable memory devices.

Contribution

It introduces a new electrical control method for exchange bias in spin-orbit torque MRAM, improving thermal stability and enabling zero-field unidirectional switching.

Findings

Current-pulse-induced exchange bias can be manipulated electrically.

Spin-orbit torque enables zero-field unidirectional switching.

Thermal agitation of magnetic moments is significantly suppressed.

Abstract

With ultra-fast writing capacity and high reliability, the spin-orbit torque is regarded as a promising alternative to fabricate next-generation magnetic random access memory. However, the three-terminal setup can be challenging when scaling down the cell size. In particular, the thermal stability is an important issue. Here we demonstrate that the current-pulse-induced perpendicular exchange bias can significantly relieve the concern of thermal stability. The switching of the exchange bias direction is induced by the spin-orbit torque when passing current pulses through the Pt/Co system with an inserted IrMn antiferromagnetic layer. Manipulating the current-pulse-induced exchange bias, spin-orbit-torque switching at zero field between states with unidirectional anisotropy is achieved and the thermal agitation of the magnetic moment is strongly suppressed. The spin-orbit torque mechanism provides an innovative method to generate and to control the exchange bias by electrical means, which enables us to realize the new switching mechanism of highly stable perpendicular memory cells.