DFT calculations identify spin-1, double Weyl, Rarita-Schwinger-Weyl, and double spin-1 excitations plus eight new type-II Weyl points without SOC and twelve more with SOC in PdAsS, PdSbSe, and PdBiTe, with orbital hybridization shaping their low-energy bands.
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Two anomalous acoustic plasmons arise from the geometry of 2D type-II Dirac cones, beyond the conventional sqrt(q) form, with valley-dependent chirality and tunability by gap and substrate.
Wave-packet dynamics in an extended graphene tight-binding model reveals the structure, emergence, and winding numbers of Dirac, hybrid, and parabolic points.
citing papers explorer
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Unconventional excitations and orbital-driven low-energy dispersions in chiral topological semimetals PdAsS, PdSbSe, and PdBiTe: a first-principles study
DFT calculations identify spin-1, double Weyl, Rarita-Schwinger-Weyl, and double spin-1 excitations plus eight new type-II Weyl points without SOC and twelve more with SOC in PdAsS, PdSbSe, and PdBiTe, with orbital hybridization shaping their low-energy bands.
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Anomalous acoustic plasmons in two-dimensional over-tilted Dirac bands
Two anomalous acoustic plasmons arise from the geometry of 2D type-II Dirac cones, beyond the conventional sqrt(q) form, with valley-dependent chirality and tunability by gap and substrate.
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Dynamically Characterizing the Structures of Dirac Points via Wave Packets
Wave-packet dynamics in an extended graphene tight-binding model reveals the structure, emergence, and winding numbers of Dirac, hybrid, and parabolic points.