Altermagnets host a purely intrinsic orbital-splitter current that is strongly anisotropic, exceeds the spin-splitter current by up to a factor of four in some directions, and generates damping-like torque to speed up magnetization switching.
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3 Pith papers cite this work. Polarity classification is still indexing.
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Pith papers citing it
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cond-mat.mes-hall 3years
2026 3verdicts
UNVERDICTED 3representative citing papers
Centrosymmetric altermagnets exhibit giant magnetic-field-induced spin magnetization of order 10^{-2} μ_B nm^{-3} at ~10 mT, controlled solely by the spin-rotation quantum metric as the only symmetry-allowed linear quantum-geometric response.
Asymmetric scattering coupled to band geometry produces a PT-odd staggered spin polarization that generates significant NSOT in collinear antiferromagnets beyond conventional Drude processes.
citing papers explorer
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Orbital-Splitter Current in Altermagnets
Altermagnets host a purely intrinsic orbital-splitter current that is strongly anisotropic, exceeds the spin-splitter current by up to a factor of four in some directions, and generates damping-like torque to speed up magnetization switching.
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Giant Spin Magnetization from Quantum Geometry in Altermagnets
Centrosymmetric altermagnets exhibit giant magnetic-field-induced spin magnetization of order 10^{-2} μ_B nm^{-3} at ~10 mT, controlled solely by the spin-rotation quantum metric as the only symmetry-allowed linear quantum-geometric response.
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Asymmetric Scattering-Induced Neel Spin-Orbit Torque in Antiferromagnets
Asymmetric scattering coupled to band geometry produces a PT-odd staggered spin polarization that generates significant NSOT in collinear antiferromagnets beyond conventional Drude processes.