Spin Hall effect emerging from a noncollinear magnetic lattice without spin-orbit coupling
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Date
2018
Volume
20
Issue
7
Journal
Series Titel
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Publisher
Bristol : Institute of Physics Publishing
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Abstract
The spin Hall effect (SHE), which converts a charge current into a transverse spin current, has long been believed to be a phenomenon induced by spin-orbit coupling. Here, we identify an alternative mechanism to realize the intrinsic SHE through a noncollinear magnetic structure that breaks the spin rotation symmetry. No spin-orbit coupling is needed even when the scalar spin chirality vanishes, different from the case of the topological Hall effect and topological SHE reported previously. In known noncollinear antiferromagnetic compounds Mn3X (X = Ga, Ge, and Sn), for example, we indeed obtain large spin Hall conductivities based on ab initio calculations.
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Keywords
antiferromagnet, spin Hall effect, spin-orbital coupling, Antiferromagnetic materials, Band structure, Calculations, Crystal symmetry, Topology, Ab initio calculations, Antiferromagnetics, Antiferromagnets, Noncollinear magnetic structures, Spin-orbit couplings, Spin-orbital coupling, Spin-rotation symmetry, Transverse spin currents, Spin Hall effect
Citation
Zhang, Y., Železný, J., Sun, Y., Van Den Brink, J., & Yan, B. (2018). Spin Hall effect emerging from a noncollinear magnetic lattice without spin-orbit coupling. 20(7). https://doi.org//10.1088/1367-2630/aad1eb
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License
CC BY 3.0 Unported