Related papers: Interpreting Multipartite Entanglement through Topological Summaries

Interpreting Multipartite Entanglement through Topological Summaries

URL: http://arxiv.org/abs/2505.00642v1
Date: Thu, 01 May 2025 16:31:36 GMT
Title: Interpreting Multipartite Entanglement through Topological Summaries
Authors: Raghav Banka, Matthew Hagan, Nathan Wiebe,
Abstract summary: The study of multipartite entanglement is much less developed than the bipartite scenario.<n>We provide a bound on the Integrated Euler Characteristic defined by Hamilton and Leditzky in citeHamilton2023probing via an average distillable entanglement.<n>We also provide a characterization of graph states via the birth and death times of the connected components and 1-dimensional cycles of the entanglement complex.
Score: 0.5097809301149342
License: http://creativecommons.org/licenses/by/4.0/
Abstract: The study of multipartite entanglement is much less developed than the bipartite scenario. Recently, a string of results \cite{diPierro_2018, mengoni2019persistenthomologyanalysismultiqubit, bart2023, hamilton2023probing} have proposed using tools from Topological Data Analysis (TDA) to attach topological quantities to multipartite states. However, these quantities are not directly connected to concrete information processing tasks making their interpretations vague. We take the first steps in connecting these abstract topological quantities to operational interpretations of entanglement in two scenarios. The first is we provide a bound on the Integrated Euler Characteristic defined by Hamilton and Leditzky in \cite{hamilton2023probing} via an average distillable entanglement, which we develop as a generalization of the Meyer-Wallach entanglement measure studied by Scott in \cite{Scott_k-uniform}. This allows us to connect the distance of an error correcting code to the Integrated Euler Characteristic. The second is we provide a characterization of graph states via the birth and death times of the connected components and 1-dimensional cycles of the entanglement complex. In other words, the entanglement distance behavior of the first Betti number $\beta_1(\varepsilon)$ allows us to determine if a state is locally equivalent to a GHZ state, potentially providing new verification schemes for highly entangled states.

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