From Entanglement Generated Dynamics to the Gravitational Anomaly and Chiral Central Charge

We apply modular flow-entanglement generated dynamics-to characterize quantum orders of ground state wave functions. In particular, we study the linear response of the entanglement entropy of a simply connected region with respect to modular flow. First, we apply it to (1+1)D conformal field theorie...

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Veröffentlicht in:	Physical review letters 2022-12, Vol.129 (26), p.260403-260403, Article 260403
1. Verfasser:	Fan, Ruihua
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container_title	Physical review letters
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creator	Fan, Ruihua
description	We apply modular flow-entanglement generated dynamics-to characterize quantum orders of ground state wave functions. In particular, we study the linear response of the entanglement entropy of a simply connected region with respect to modular flow. First, we apply it to (1+1)D conformal field theories and demonstrate its relationship to the chiral central charge-or, equivalently, the perturbative gravitational anomaly-which is shown to vanish. Next, we apply it to (2+1)D gapped ground states where it reduces to a recently proposed formula by Kim et al. that is conjectured to compute the edge chiral central charge. Modular flow provides an intuitive picture for this conjecture based on bulk-edge correspondence. We also provide numerics on free-fermion models that lend support to our picture.
doi_str_mv	10.1103/PhysRevLett.129.260403
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title	From Entanglement Generated Dynamics to the Gravitational Anomaly and Chiral Central Charge
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