Anton Kapustin, Nikita Sopenko
Published 2020-06-25Version 1
We study charge transport for zero-temperature infinite-volume gapped lattice systems in two dimensions with short-range interactions. We show that the Hall conductance is locally computable and is the same for all systems which are in the same gapped phase. We provide a rigorous versions of Laughlin's flux-insertion argument which shows that for short-range entangled systems the Hall conductance is an integer multiple of e^2/h. We show that the Hall conductance determines the statistics of flux insertions. For bosonic short-range entangled systems, this implies that the Hall conductance is an even multiple of e^2/h. Finally, we adapt a proof of quantization of the Thouless charge pump to the case of infinite-volume gapped lattice systems in one dimension.
Quantization of the Hall conductance and delocalization in ergodic Landau Hamiltonians
Quantization of Hall Conductance For Interacting Electrons Without Averaging Assumptions
Representations and Properties of Generalized $A_r$ Statistics, Coherent States and Robertson Uncertainty Relations
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