Hyperspatial projections of decorated Ammann-Beenker and Penrose lattices host interaction-induced Néel order that realizes g-wave and h-wave altermagnetism compatible with quasicrystalline symmetries.
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Orbital altermagnetism is defined as a symmetry-protected order of orbital magnetic moments with d-wave-like momentum locking, shown via tight-binding models and DFT in materials such as CuBr2, VS2, MoO and CrO.
A weak crystal potential in d-wave altermagnets induces real-space spin quadrupolar order without unit cell enlargement.
citing papers explorer
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Unconventional Altermagnetism in Quasicrystals: A Hyperspatial Projective Construction
Hyperspatial projections of decorated Ammann-Beenker and Penrose lattices host interaction-induced Néel order that realizes g-wave and h-wave altermagnetism compatible with quasicrystalline symmetries.
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Orbital Altermagnetism
Orbital altermagnetism is defined as a symmetry-protected order of orbital magnetic moments with d-wave-like momentum locking, shown via tight-binding models and DFT in materials such as CuBr2, VS2, MoO and CrO.
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Spin Quadrupolar orders in $d$-wave Unconventional Magnetism
A weak crystal potential in d-wave altermagnets induces real-space spin quadrupolar order without unit cell enlargement.