Anomalous Hall Effect Driven by Chiral Superconductivity
摘要
Direct dc-current signatures of unconventional superconductivity remain scarce. Existing probes of unconventional pairing are typically indirect, relying on phase-diagram anomalies, responses to external fields, or optical measurements. Here we propose a zero-field Hall drag effect as a direct transport signature of chiral superconductivity. The effect arises from Coulomb drag between quasiparticles in a chiral superconductor and those in an adjacent time-reversal-symmetric normal layer. We develop a minimal hydrodynamic theory that includes both quasiparticle normal current and condensate supercurrent in the superconducting layer. In an open-circuit superconducting layer, the condensate generates a counterflowing supercurrent that cancels the net layer current, while a finite quasiparticle current remains and mediates the transverse drag response. This results in anomalous Hall voltage signal appearing abruptly when is lowered below , of the sign reflecting the sign of the superconducting order parameter phase winding.
引用
@article{arxiv.2606.31851,
title = {Anomalous Hall Effect Driven by Chiral Superconductivity},
author = {Vladislav Poliakov and Alex Levchenko and Leonid Levitov},
journal= {arXiv preprint arXiv:2606.31851},
year = {2026}
}