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Symmetry-resolved entanglement in symmetry-protected topological phases

arXiv
Authors: Daniel Azses, Eran Sela

Year

2020

Paper ID

21300

Status

Preprint

Abstract Read

~2 min

Abstract Words

111

Citations

N/A

Abstract

Symmetry protected topological phases (SPTs) have universal degeneracies in the entanglement spectrum in one dimension (1D). Here, we formulate this phenomenon in the framework of symmetry-resolved entanglement (SRE) using cohomology theory. We develop a general approach to compute entanglement measures of SPTs in any dimension and specifically SRE via a discrete path integral on multi-sheet Riemann surfaces with generalized defects. The resulting path integral is expressed in terms of group cocycles describing the topological actions of SPTs. Their cohomology classification allows to identify universal entanglement properties. Specifically, we demonstrate an equi-block decomposition of the reduced density matrix into symmetry sectors, for all 1D topological phases protected by finite Abelian unitary symmetries.

Why This Paper Matters

  • It adds a 2020 reference point for readers tracking recent quantum research.
  • Symmetry protected topological phases (SPTs) have universal degeneracies in the entanglement spectrum in one dimension (1D).

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