Quantum fluctuations stabilize a chiral ferromagnet with orbital chirality and a chiral stripe phase in the presence of magnetization-non-conserving spin-orbit interactions, producing an enhanced thermal Hall effect.
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Quantum fluctuations generate nonzero scalar spin chirality in collinear or coplanar magnetic orders on a triangular lattice with XXZ and spin-orbit interactions under magnetic field.
Exchange anisotropy Δ in X₂YCo(PO₄)₂ and X₂Co(SeO₃)₂ families is determined by the ratio of trigonal crystal field to spin-orbit coupling, providing a microscopic design rule for spin supersolids.
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Fluctuation-driven chiral ferromagnetism
Quantum fluctuations stabilize a chiral ferromagnet with orbital chirality and a chiral stripe phase in the presence of magnetization-non-conserving spin-orbit interactions, producing an enhanced thermal Hall effect.
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A microscopic design rule for spin supersolids in triangular-lattice magnets
Exchange anisotropy Δ in X₂YCo(PO₄)₂ and X₂Co(SeO₃)₂ families is determined by the ratio of trigonal crystal field to spin-orbit coupling, providing a microscopic design rule for spin supersolids.