Isolated bands with quantum metric exhibit a disorder-induced localization length plateau at approximately twice the quantum metric length, protected until disorder exceeds the band gap.
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4 Pith papers cite this work. Polarity classification is still indexing.
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Pith papers citing it
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Collective fluctuations generate dynamical Berry curvature via non-commutative transverse quantum fluctuations and non-local-time interactions, distinguishable from bare band geometry in antisymmetric inelastic scattering channels.
A symmetry-based method using field-reversal and angular dependence disentangles anisotropy and Berry curvature contributions to in-plane Hall responses, demonstrated on Fe3Sn.
Counterflow conductivity in magnetoexciton bands serves as a tunable probe of the quantum geometric dipole carried by interlayer excitons.
citing papers explorer
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Quantum Metric Localization and Quantum Metric Protection
Isolated bands with quantum metric exhibit a disorder-induced localization length plateau at approximately twice the quantum metric length, protected until disorder exceeds the band gap.
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Geometric curvature driven by many-body collective fluctuations
Collective fluctuations generate dynamical Berry curvature via non-commutative transverse quantum fluctuations and non-local-time interactions, distinguishable from bare band geometry in antisymmetric inelastic scattering channels.
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Distinguishing and Separating In-Plane Hall Responses
A symmetry-based method using field-reversal and angular dependence disentangles anisotropy and Berry curvature contributions to in-plane Hall responses, demonstrated on Fe3Sn.
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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.