Robust chiral spin transport in the antiferromagnetic iron oxide/heavy metal bilayers

Zhang, T. Z.; Meng, K. K.; Wu, Y.; Chen, J. K.; Xu, X. G.; Jiang, Y.

doi:10.1063/5.0207742

Applied Physics Letters

2024

DOI: 10.1063/5.0207742

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Robust chiral spin transport in the antiferromagnetic iron oxide/heavy metal bilayers

T. Z. Zhang,

K. K. Meng,

Y. Wu

et al.

Abstract: We have observed robust chiral spin torques and non-reciprocal charge transport behaviors in the α-Fe2O3/Pt bilayers through a combination of magnetic field and current-dependent second longitudinal harmonic resistance measurements. The interfacial Dzyaloshinskii–Moriya interaction induced magnetic chirality has been predicted to account for the sign reversal characteristic of the second longitudinal harmonic resistance with increasing the current amplitude. A physical model that considers the chirality depend… Show more

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Enhancing Field‐Like Efficiency Via Interface Engineering with Sub‐Atomic Layer Ta Insertion

Wang,

He,

et al. 2024

Advanced Science

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The prevailing research emphasis has been on reducing the critical switching current density (Jc) by enhancing the damping‐like efficiency (βDL). However, recent studies have shown that the field‐like efficiency (βFL) can also play a major role in reducing Jc. In this study, the central inversion asymmetry of Pt‐Co is significantly enhanced through interface engineering at the sub‐atomic layer of Ta, thereby inducing substantial alterations in the βFL associated with the interface. The βFL has shown a 123% increase, from −1.66 Oe/(MA cm−2) to ‐3.8 Oe/(MA cm−2). As a result, the multilayered Ta/Pt/Ta (0.3 nm insertion)/Co/Ta structure leads to a notable decrease in Jc, exceeding a remarkable 90% compared to the simpler Ta/Pt/Co/Ta structure, ultimately achieving a significantly low value of 2.7 MA cm−2. These findings pave the way for the development of highly efficient and energy‐saving spin‐orbit torque (SOT)‐based spintronic devices, where further optimizations in interface engineering can unlock even greater potential in terms of reduced power consumption and enhanced performance.

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Enhancing Field‐Like Efficiency Via Interface Engineering with Sub‐Atomic Layer Ta Insertion

Wang,

He,

et al. 2024

Advanced Science

View full text Add to dashboard Cite

show abstract

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Robust chiral spin transport in the antiferromagnetic iron oxide/heavy metal bilayers

Cited by 1 publication

References 57 publications

Enhancing Field‐Like Efficiency Via Interface Engineering with Sub‐Atomic Layer Ta Insertion

Enhancing Field‐Like Efficiency Via Interface Engineering with Sub‐Atomic Layer Ta Insertion

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