Crystalline antiunitary symmetry in altermagnets selects pairing that produces robust nodal topological superconducting phases with Majorana flat bands and chiral edge states.
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An inhomogeneous altermagnetic interlayer in a Josephson junction produces enhanced critical current and spin-polarized supercurrent at π misorientation of Néel vectors through cancellation of pair-breaking oscillations.
Inter-subband coupling in multichannel Rashba nanowire Josephson junctions confines the topological phase to finite Zeeman fields, enables JDE for spin-orbit-aligned Zeeman fields, and increases diode efficiency via enhanced spectral asymmetry and Majorana bound states.
citing papers explorer
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Nodal Topological Superconductivity Driven by Crystalline Antiunitary Symmetry in Altermagnets
Crystalline antiunitary symmetry in altermagnets selects pairing that produces robust nodal topological superconducting phases with Majorana flat bands and chiral edge states.
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Spin-polarized Josephson current induced by inhomogeneous altermagnetic interlayers
An inhomogeneous altermagnetic interlayer in a Josephson junction produces enhanced critical current and spin-polarized supercurrent at π misorientation of Néel vectors through cancellation of pair-breaking oscillations.
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Josephson diode effect in multichannel Rashba nanowires: Role of inter-subband coupling
Inter-subband coupling in multichannel Rashba nanowire Josephson junctions confines the topological phase to finite Zeeman fields, enables JDE for spin-orbit-aligned Zeeman fields, and increases diode efficiency via enhanced spectral asymmetry and Majorana bound states.