TbB4 hosts component-resolved mixed-parity spin textures in a 3D compensated magnet, with p/f-wave odd parity in-plane and d-wave even parity out-of-plane, driven by staggered Berry phase from scalar spin chirality.
R.et al.Antialtermagnetic magnons and nonrelativistic thermal edelstein effect.arXiv preprint arXiv:2603.05415(2026)
7 Pith papers cite this work. Polarity classification is still indexing.
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Chiral nanotubes from collinear magnets realize p-wave magnetism with p-wave spin splitting independent of the parent collinear order.
Odd-parity magnon splitting is classified in 2D collinear antiferromagnets and induced by circularly polarized light or loop currents, driving topological transitions with chiral edge modes in bilayers.
Collinear antiferromagnetic multiferroics host odd-parity chiral magnons in f-wave, p-wave, and fully-gapped forms that are reversible by ferroelectric switching, identified via magnetic group analysis, spin-wave calculations, and DFT.
Topological exciton condensation in the Haldane-Hubbard model produces a Néel state with odd-parity magnons showing f-wave splitting and topology changes tied to electron bandgap closing.
ARPES measurements on CeNiAsO reveal absence of expected p-wave band splitting and c-f hybridization, showing that localized Ce 4f electrons quench nonrelativistic spin splitting.
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.
citing papers explorer
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Unconventional Mixed-Parity Magnetism in Rare-Earth Tetraborides
TbB4 hosts component-resolved mixed-parity spin textures in a 3D compensated magnet, with p/f-wave odd parity in-plane and d-wave even parity out-of-plane, driven by staggered Berry phase from scalar spin chirality.
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Rolling Two-Dimensional Collinear Magnets into Chiral Nanotubes with $p$-Wave Magnetism
Chiral nanotubes from collinear magnets realize p-wave magnetism with p-wave spin splitting independent of the parent collinear order.
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Odd-Parity Magnons
Odd-parity magnon splitting is classified in 2D collinear antiferromagnets and induced by circularly polarized light or loop currents, driving topological transitions with chiral edge modes in bilayers.
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Odd-Parity Chiral Magnons in Collinear Antiferromagnetic Multiferroics: Symmetry Classification and Ferroelectric Switching
Collinear antiferromagnetic multiferroics host odd-parity chiral magnons in f-wave, p-wave, and fully-gapped forms that are reversible by ferroelectric switching, identified via magnetic group analysis, spin-wave calculations, and DFT.
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Odd-parity magnons in the Haldane-Hubbard model from topological exciton condensation
Topological exciton condensation in the Haldane-Hubbard model produces a Néel state with odd-parity magnons showing f-wave splitting and topology changes tied to electron bandgap closing.
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Quenching of Nonrelativistic p-Wave Spin Splitting by c-f Decoupling in CeNiAsO
ARPES measurements on CeNiAsO reveal absence of expected p-wave band splitting and c-f hybridization, showing that localized Ce 4f electrons quench nonrelativistic spin splitting.
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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.