A theory is derived for disorder-induced time-reversal-odd nonlinear spin and orbital Hall effects, including a scaling relation to distinguish mechanisms and model results showing orbital contributions can exceed spin ones.
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In the α-T3 lattice with on-site asymmetry, mean-field theory shows a superconducting gap that grows as a power law with interaction strength at flat-band filling, while the geometric part of the superfluid weight grows linearly and is enhanced by tuning α.
Planar magnetotransport yields distinct quantum-geometric fingerprints of d-, g-, and i-wave altermagnetic order via magnetic-field-induced Berry curvature and quantum metric susceptibilities.
citing papers explorer
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Disorder induced time-reversal-odd nonlinear spin and orbital Hall effects
A theory is derived for disorder-induced time-reversal-odd nonlinear spin and orbital Hall effects, including a scaling relation to distinguish mechanisms and model results showing orbital contributions can exceed spin ones.
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Superconductivity and geometric superfluid weight of a tunable flat band system
In the α-T3 lattice with on-site asymmetry, mean-field theory shows a superconducting gap that grows as a power law with interaction strength at flat-band filling, while the geometric part of the superfluid weight grows linearly and is enhanced by tuning α.
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Quantum-Geometric Fingerprints of Altermagnetic Order in Planar Magnetotransport
Planar magnetotransport yields distinct quantum-geometric fingerprints of d-, g-, and i-wave altermagnetic order via magnetic-field-induced Berry curvature and quantum metric susceptibilities.