Non-uniform Berry curvature in parent Chern bands induces momentum-space vortices in the chiral superconducting gap function, with the parent Chern number constraining vortex count independently of model details.
Title resolution pending
4 Pith papers cite this work. Polarity classification is still indexing.
4
Pith papers citing it
years
2026 4verdicts
UNVERDICTED 4representative citing papers
Excitons between moiré flat Chern bands acquire giant helical dipoles from Berry curvature, with displacement field driving a Frenkel-Wannier transition and formation of quadrupolar biexcitons.
Shift vectors are reinterpreted as the intrinsic dipole moment of a single correlated electronic state, recovering prior expressions as special cases.
Counterflow conductivity in magnetoexciton bands serves as a tunable probe of the quantum geometric dipole carried by interlayer excitons.
citing papers explorer
-
Chiral superconductors from parent states with non-uniform Berry curvature: Momentum-space vortices, BdG topology, and thermal Hall conductivity
Non-uniform Berry curvature in parent Chern bands induces momentum-space vortices in the chiral superconducting gap function, with the parent Chern number constraining vortex count independently of model details.
-
Giant and Helical Exciton Dipole from Berry Curvature in Flat Chern Bands
Excitons between moiré flat Chern bands acquire giant helical dipoles from Berry curvature, with displacement field driving a Frenkel-Wannier transition and formation of quadrupolar biexcitons.
-
Generalized Shift Vector as the Intrinsic Dipole of Many-Body Correlated Electronic States
Shift vectors are reinterpreted as the intrinsic dipole moment of a single correlated electronic state, recovering prior expressions as special cases.
-
Signatures of the Quantum Geometric Dipole of Interlayer Excitons in Counterflow Conductivity
Counterflow conductivity in magnetoexciton bands serves as a tunable probe of the quantum geometric dipole carried by interlayer excitons.