A nonlinear orbital Hall effect odd in the Néel vector unifies electrical readout of antiferromagnetic switching with orbital torque writing to ferromagnets via spin-orbit coupling.
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Spin torque from inhomogeneous current produces periodic magnonic frequency modulation in a bicomponent nanopatterned crystal, resulting in avoided crossings and tunable hybrid modes between localized and propagating Damon-Eshbach waves.
First-principles study demonstrates spin-orbit torque switching of Néel order and layer-resolved Chern marker in band-inverted antiferromagnetic bilayer MnBi2Te4.
citing papers explorer
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Nonlinear Magnetic Orbital Hall Effect Induced by Spin-Orbit Coupling
A nonlinear orbital Hall effect odd in the Néel vector unifies electrical readout of antiferromagnetic switching with orbital torque writing to ferromagnets via spin-orbit coupling.
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Spin torque driven mode hybridization and band engineering in nanopatterned magnonic crystals
Spin torque from inhomogeneous current produces periodic magnonic frequency modulation in a bicomponent nanopatterned crystal, resulting in avoided crossings and tunable hybrid modes between localized and propagating Damon-Eshbach waves.
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Spin-orbit torque switching of N\'eel order in band-inverted antiferromagnetic bilayer MnBi$_2$Te$_4$
First-principles study demonstrates spin-orbit torque switching of Néel order and layer-resolved Chern marker in band-inverted antiferromagnetic bilayer MnBi2Te4.