Piezospintronic effect in honeycomb antiferromagnets

Camilo Ulloa; Roberto E. Troncoso; Scott A. Bender; R. A. Duine; A.S. Nunez

doi:10.1103/PhysRevB.96.104419

Piezospintronic effect in honeycomb antiferromagnets

Camilo Ulloa, Roberto E. Troncoso, Scott A. Bender, R. A. Duine, A.S. Nunez

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

Abstract

The emission of pure spin currents by mechanical deformations, the piezospintronic effect, in antiferromagnets is studied. We characterize the piezospintronic effect in an antiferromagnetic honeycomb monolayer in response to external strains. It is shown that the strain tensor components can be evaluated in terms of the spin Berry phase. In addition, we propose an experimental setup to detect the piezo-spin current generated in the piezospintronic material through the inverse spin Hall effect. Our results apply to a wide family of two-dimensional antiferromagnetic materials without inversion symmetry, such as the transition-metal chalcogenophosphates materials MPX3 (M=V, Mn; X=S, Se, Te) and NiPSe3.

Original language	English
Article number	104419
Journal	Physical Review B - Condensed Matter and Materials Physics
Volume	96
Issue number	10
DOIs	https://doi.org/10.1103/PhysRevB.96.104419
Publication status	Published - 14 Sept 2017

Keywords

Antiferromagnetism
Geometric & topological phases
Honeycomb lattice

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title = "Piezospintronic effect in honeycomb antiferromagnets",

abstract = "The emission of pure spin currents by mechanical deformations, the piezospintronic effect, in antiferromagnets is studied. We characterize the piezospintronic effect in an antiferromagnetic honeycomb monolayer in response to external strains. It is shown that the strain tensor components can be evaluated in terms of the spin Berry phase. In addition, we propose an experimental setup to detect the piezo-spin current generated in the piezospintronic material through the inverse spin Hall effect. Our results apply to a wide family of two-dimensional antiferromagnetic materials without inversion symmetry, such as the transition-metal chalcogenophosphates materials MPX3 (M=V, Mn; X=S, Se, Te) and NiPSe3.",

keywords = "Antiferromagnetism, Geometric & topological phases, Honeycomb lattice",

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AU - Ulloa, Camilo

AU - Troncoso, Roberto E.

AU - Bender, Scott A.

AU - Duine, R. A.

AU - Nunez, A.S.

PY - 2017/9/14

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N2 - The emission of pure spin currents by mechanical deformations, the piezospintronic effect, in antiferromagnets is studied. We characterize the piezospintronic effect in an antiferromagnetic honeycomb monolayer in response to external strains. It is shown that the strain tensor components can be evaluated in terms of the spin Berry phase. In addition, we propose an experimental setup to detect the piezo-spin current generated in the piezospintronic material through the inverse spin Hall effect. Our results apply to a wide family of two-dimensional antiferromagnetic materials without inversion symmetry, such as the transition-metal chalcogenophosphates materials MPX3 (M=V, Mn; X=S, Se, Te) and NiPSe3.

AB - The emission of pure spin currents by mechanical deformations, the piezospintronic effect, in antiferromagnets is studied. We characterize the piezospintronic effect in an antiferromagnetic honeycomb monolayer in response to external strains. It is shown that the strain tensor components can be evaluated in terms of the spin Berry phase. In addition, we propose an experimental setup to detect the piezo-spin current generated in the piezospintronic material through the inverse spin Hall effect. Our results apply to a wide family of two-dimensional antiferromagnetic materials without inversion symmetry, such as the transition-metal chalcogenophosphates materials MPX3 (M=V, Mn; X=S, Se, Te) and NiPSe3.

KW - Antiferromagnetism

KW - Geometric & topological phases

KW - Honeycomb lattice

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DO - 10.1103/PhysRevB.96.104419

M3 - Article

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JO - Physical Review B - Condensed Matter and Materials Physics

JF - Physical Review B - Condensed Matter and Materials Physics

IS - 10

M1 - 104419

ER -

Piezospintronic effect in honeycomb antiferromagnets

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Keywords

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