Intrinsic Nonlinear Spin Hall Effect and Manipulation of Perpendicular Magnetization

Hui Wang; Huiying Liu; Xukun Feng; Jin Cao; Weikang Wu; Shen Lai; Weibo Gao; Cong Xiao; Shengyuan A. Yang

doi:10.1103/PhysRevLett.134.056301

Intrinsic Nonlinear Spin Hall Effect and Manipulation of Perpendicular Magnetization

Hui Wang
, Huiying Liu
, Xukun Feng
, Jin Cao
, Weikang Wu
, Shen Lai
, Weibo Gao^*
, Cong Xiao^*
, Shengyuan A. Yang

^*Corresponding author for this work

School of Physics

Research output: Contribution to journal › Article › peer-review

5 Scopus citations

Abstract

We propose an intrinsic nonlinear spin Hall effect, which enables the generation of collinearly polarized spin current in a large class of nonmagnetic materials with the corresponding linear response being symmetry forbidden. This opens a new avenue for field-free switching of perpendicular magnetization, which is required for the next-generation information storage technology. We develop the microscopic theory of this effect and clarify its quantum origin in band geometric quantities which can be enhanced by topological nodal features. Combined with first-principles calculations, we predict pronounced effects at room temperature in topological metals PbTaSe2 and PdGa. Our work establishes a fundamental nonlinear response in spin transport and opens the door to exploring spintronic applications based on nonlinear spin Hall effect.

Original language	English
Article number	056301
Journal	Physical Review Letters
Volume	134
Issue number	5
DOIs	https://doi.org/10.1103/PhysRevLett.134.056301
State	Published - 7 Feb 2025

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10.1103/PhysRevLett.134.056301

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title = "Intrinsic Nonlinear Spin Hall Effect and Manipulation of Perpendicular Magnetization",

abstract = "We propose an intrinsic nonlinear spin Hall effect, which enables the generation of collinearly polarized spin current in a large class of nonmagnetic materials with the corresponding linear response being symmetry forbidden. This opens a new avenue for field-free switching of perpendicular magnetization, which is required for the next-generation information storage technology. We develop the microscopic theory of this effect and clarify its quantum origin in band geometric quantities which can be enhanced by topological nodal features. Combined with first-principles calculations, we predict pronounced effects at room temperature in topological metals PbTaSe2 and PdGa. Our work establishes a fundamental nonlinear response in spin transport and opens the door to exploring spintronic applications based on nonlinear spin Hall effect.",

author = "Hui Wang and Huiying Liu and Xukun Feng and Jin Cao and Weikang Wu and Shen Lai and Weibo Gao and Cong Xiao and Yang, \{Shengyuan A.\}",

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AU - Wang, Hui

AU - Liu, Huiying

AU - Feng, Xukun

AU - Cao, Jin

AU - Wu, Weikang

AU - Lai, Shen

AU - Gao, Weibo

AU - Xiao, Cong

AU - Yang, Shengyuan A.

PY - 2025/2/7

Y1 - 2025/2/7

N2 - We propose an intrinsic nonlinear spin Hall effect, which enables the generation of collinearly polarized spin current in a large class of nonmagnetic materials with the corresponding linear response being symmetry forbidden. This opens a new avenue for field-free switching of perpendicular magnetization, which is required for the next-generation information storage technology. We develop the microscopic theory of this effect and clarify its quantum origin in band geometric quantities which can be enhanced by topological nodal features. Combined with first-principles calculations, we predict pronounced effects at room temperature in topological metals PbTaSe2 and PdGa. Our work establishes a fundamental nonlinear response in spin transport and opens the door to exploring spintronic applications based on nonlinear spin Hall effect.

AB - We propose an intrinsic nonlinear spin Hall effect, which enables the generation of collinearly polarized spin current in a large class of nonmagnetic materials with the corresponding linear response being symmetry forbidden. This opens a new avenue for field-free switching of perpendicular magnetization, which is required for the next-generation information storage technology. We develop the microscopic theory of this effect and clarify its quantum origin in band geometric quantities which can be enhanced by topological nodal features. Combined with first-principles calculations, we predict pronounced effects at room temperature in topological metals PbTaSe2 and PdGa. Our work establishes a fundamental nonlinear response in spin transport and opens the door to exploring spintronic applications based on nonlinear spin Hall effect.

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VL - 134

JO - Physical Review Letters

JF - Physical Review Letters

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Intrinsic Nonlinear Spin Hall Effect and Manipulation of Perpendicular Magnetization

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