Pairing in chiral superconductors induces effective momentum-space magnetism that enables optical anomalous Hall conductivity, with unitary pairing requiring normal-state spin-orbit coupling to produce ferromagnetism or antiferromagnetic textures.
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Zn doping in FeSe produces nonmonotonic Tc evolution and preserves robust multigap superconductivity consisting of an isotropic s-wave gap plus an anisotropic extended s-wave gap.
RPA calculation finds mixed even-odd parity gaps from anisotropic SOC in noncentrosymmetric wells and mixed even-odd frequency order parameters in superconductor-ferromagnet junctions.
citing papers explorer
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Pairing-induced Momentum-space Magnetism and Its Implication In Optical Anomalous Hall Effect In Chiral Superconductors
Pairing in chiral superconductors induces effective momentum-space magnetism that enables optical anomalous Hall conductivity, with unitary pairing requiring normal-state spin-orbit coupling to produce ferromagnetism or antiferromagnetic textures.
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Nonmonotonic Evolution of the Superconducting Transition Temperature and Robust Multigap Extended s-wave + s-wave Pairing in Zn-Substituted FeSe Single Crystals
Zn doping in FeSe produces nonmonotonic Tc evolution and preserves robust multigap superconductivity consisting of an isotropic s-wave gap plus an anisotropic extended s-wave gap.
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Superconductivity of mixed parity and frequency in an anisotropic spin-orbit coupling
RPA calculation finds mixed even-odd parity gaps from anisotropic SOC in noncentrosymmetric wells and mixed even-odd frequency order parameters in superconductor-ferromagnet junctions.