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Paper detail

Interaction-induced chiral-transport inversion

We investigate the chiral dynamics of locally interacting bosons in a two-leg flux ladder, where on-site interactions, despite being fully isotropic, counterintuitively reverse the flux-induced chiral transport of density distribution. For a Bose-Einstein condensate (in the mean-field regime), this reversal arises from an interactiondriven dynamical band-occupation inversion, which selectively populates single-particle states of the opposing chirality. Strikingly, the chiral-transport inversion has a few-body, hence beyond-mean-field, origin, as the formation of two-body bound states with reversed chirality dominates the few-body dynamics. This dual pathway, that is, occupation inversion and bound-state formation, underlies the chiral-transport inversion, which challenges the conventional wisdom that isotropic interactions cannot bias density transport. Our work reveals the interplay between interactions and chirality and highlights how correlations engineer exotic quantum transport.

preprint2026arXivOpen access
Li PanQian LiangChang-An YangYu HuangPengjie LiuFanying XiWei YiXiaofan ZhouJian-Song Pan
cond-mat.quant-gas
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Li PanQian LiangChang-An YangYu HuangPengjie LiuFanying XiWei YiXiaofan ZhouJian-Song Pan

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