Relativistic altermagnets exhibit mixed g-, d-, and p-wave spin-momentum locking with symmetry-protected nodal planes and accidental nodal surfaces depending on Néel vector orientation.
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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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2026 3verdicts
UNVERDICTED 3representative citing papers
A minimal 2D d-wave altermagnetic model with band inversion realizes a ferroelectrically tunable Chern insulator with spontaneous spin canting, enabling C = ±1 and ±2 phases via Berry-curvature reorganization.
Orbital chiral flux breaks a hidden antiunitary symmetry in a coplanar kagome altermagnet, activating Berry curvature and Hall conductivity in the complete absence of spin-orbit coupling.
citing papers explorer
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Symmetry-protected nodal planes and accidental nodal surfaces in mixed odd-even wave spin-momentum locking of relativistic altermagnets
Relativistic altermagnets exhibit mixed g-, d-, and p-wave spin-momentum locking with symmetry-protected nodal planes and accidental nodal surfaces depending on Néel vector orientation.
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Ferroelectric Altermagnetic Chern Insulator in magnetic field: electrical control of the Chern number
A minimal 2D d-wave altermagnetic model with band inversion realizes a ferroelectrically tunable Chern insulator with spontaneous spin canting, enabling C = ±1 and ±2 phases via Berry-curvature reorganization.
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Berry-Curvature Activation by Orbital Flux in a Kagome Altermagnet
Orbital chiral flux breaks a hidden antiunitary symmetry in a coplanar kagome altermagnet, activating Berry curvature and Hall conductivity in the complete absence of spin-orbit coupling.