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Main Authors: Monaco, Gabriele Lo, Innocenti, Luca, Cilluffo, Dario, Chisholm, Diana A., Lorenzo, Salvatore, Palma, G. Massimo
Format: Preprint
Published: 2023
Subjects:
Online Access:https://arxiv.org/abs/2312.11619
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author Monaco, Gabriele Lo
Innocenti, Luca
Cilluffo, Dario
Chisholm, Diana A.
Lorenzo, Salvatore
Palma, G. Massimo
author_facet Monaco, Gabriele Lo
Innocenti, Luca
Cilluffo, Dario
Chisholm, Diana A.
Lorenzo, Salvatore
Palma, G. Massimo
contents Quantum information scrambling (QIS) is a characteristic feature of several quantum systems, ranging from black holes to quantum communication networks. While accurately quantifying QIS is crucial to understanding many such phenomena, common approaches based on the tripartite information have limitations due to the accessibility issues of quantum mutual information, and do not always properly take into consideration the dependence on the encoding input basis. To address these issues, we propose a novel and computationally efficient QIS quantifier, based on a formulation of QIS in terms of quantum state discrimination. We show that the optimal guessing probability, which reflects the degree of QIS induced by an isometric quantum evolution, is directly connected to the accessible min-information, a generalized channel capacity based on conditional min-entropy, which can be cast as a convex program and thus computed efficiently. By applying our proposal to a range of examples with increasing complexity, we illustrate its ability to capture the multifaceted nature of QIS in all its intricacy.
format Preprint
id arxiv_https___arxiv_org_abs_2312_11619
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle An operational definition of quantum information scrambling
Monaco, Gabriele Lo
Innocenti, Luca
Cilluffo, Dario
Chisholm, Diana A.
Lorenzo, Salvatore
Palma, G. Massimo
Quantum Physics
High Energy Physics - Theory
Quantum information scrambling (QIS) is a characteristic feature of several quantum systems, ranging from black holes to quantum communication networks. While accurately quantifying QIS is crucial to understanding many such phenomena, common approaches based on the tripartite information have limitations due to the accessibility issues of quantum mutual information, and do not always properly take into consideration the dependence on the encoding input basis. To address these issues, we propose a novel and computationally efficient QIS quantifier, based on a formulation of QIS in terms of quantum state discrimination. We show that the optimal guessing probability, which reflects the degree of QIS induced by an isometric quantum evolution, is directly connected to the accessible min-information, a generalized channel capacity based on conditional min-entropy, which can be cast as a convex program and thus computed efficiently. By applying our proposal to a range of examples with increasing complexity, we illustrate its ability to capture the multifaceted nature of QIS in all its intricacy.
title An operational definition of quantum information scrambling
topic Quantum Physics
High Energy Physics - Theory
url https://arxiv.org/abs/2312.11619