Reversal of Spin-Torque Polarity with Inverting Current Vorticity in Composition-Graded Layer at the Ti/W Interface

IF 5.3 2区材料科学 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY

Advanced Electronic Materials Pub Date : 2025-04-08 DOI:10.1002/aelm.202400797

Hayato Nakayama, Taisuke Horaguchi, Jun Uzuhashi, Cong He, Hiroaki Sukegawa, Tadakatsu Ohkubo, Seiji Mitani, Kazuto Yamanoi, Yukio Nozaki

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Abstract

While compositional gradient-induced spin-current generation is explored, its microscopic mechanisms remain poorly understood. Here, the contribution of polarity of compositional gradient on spin-current generation is explored. A nanoscale compositional gradient, formed by in situ atomic diffusion of ultrathin Ti and W layers, is introduced between 10-nm-thick W and Ti layers. Spin-torque ferromagnetic resonance in ferromagnetic Ni₉₅Cu₅ deposited on this gradient reveals that a moderate compositional gradient suppresses negative spin torque from the spin Hall effect in W. In contrast, reversing the Ti/W stacking order, which inverts the gradient, suppresses positive spin torque from the orbital Hall effect in Ti. These findings suggest that the sign of spin torque is governed by the polarity of compositional gradient, providing a novel strategy for efficient spin-torque generation without relying on materials with strong spin or orbital Hall effect.

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Ti/W界面成分梯度层中电流涡度反转的自旋-转矩极性

虽然对成分梯度诱导的自旋电流产生进行了探索，但对其微观机制仍然知之甚少。本文探讨了成分梯度的极性对自旋电流产生的影响。在 10 纳米厚的 W 层和 Ti 层之间引入了由超薄 Ti 层和 W 层的原位原子扩散形成的纳米级成分梯度。沉积在这一梯度上的铁磁性 Ni95Cu5 中的自旋力矩铁磁共振显示，适度的成分梯度抑制了 W 中自旋霍尔效应产生的负自旋力矩。这些研究结果表明，自旋力矩的符号受成分梯度极性的制约，为高效产生自旋力矩提供了一种新策略，而无需依赖具有强自旋或轨道霍尔效应的材料。

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来源期刊

Advanced Electronic Materials NANOSCIENCE & NANOTECHNOLOGYMATERIALS SCIE-MATERIALS SCIENCE, MULTIDISCIPLINARY

CiteScore

11.00

自引率

3.20%

发文量

433

期刊介绍： Advanced Electronic Materials is an interdisciplinary forum for peer-reviewed, high-quality, high-impact research in the fields of materials science, physics, and engineering of electronic and magnetic materials. It includes research on physics and physical properties of electronic and magnetic materials, spintronics, electronics, device physics and engineering, micro- and nano-electromechanical systems, and organic electronics, in addition to fundamental research.