TMD monolayers exhibit an orbital Nernst effect independent of spin-orbit coupling and a spin Nernst effect that scales with it, both tunable by doping and arising from Berry curvatures.
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P-wave orbital magnetism protected by combined translation and time-reversal symmetry is proposed to originate from loop-current-induced orbital textures in a 2D Dirac lattice model, measurable via orbital Hall conductivity.
Derives corrected orbital magnetic moment matrix elements for non-degenerate Bloch states including Berry connection contributions and shows reduced orbital Hall conductivity in bilayer TMDC and graphene systems.
citing papers explorer
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Orbital and Spin Nernst Effects in Monolayers of Transition Metal Dichalcogenides
TMD monolayers exhibit an orbital Nernst effect independent of spin-orbit coupling and a spin Nernst effect that scales with it, both tunable by doping and arising from Berry curvatures.
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$P$-wave Orbital Magnetism
P-wave orbital magnetism protected by combined translation and time-reversal symmetry is proposed to originate from loop-current-induced orbital textures in a 2D Dirac lattice model, measurable via orbital Hall conductivity.
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Orbital Hall effect from orbital magnetic moments of Bloch states: the role of a new correction term
Derives corrected orbital magnetic moment matrix elements for non-degenerate Bloch states including Berry connection contributions and shows reduced orbital Hall conductivity in bilayer TMDC and graphene systems.