Entanglement between dependent degrees of freedom: Quasi-particle correlations

Common notions of entanglement are based on well-separated subsystems. However, obtaining such independent degrees of freedom is not always possible because of physical constraints. In this work, we explore the notion of entanglement in the context of dependent degrees of freedom. As a physically re...

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Veröffentlicht in:	arXiv.org 2024-10
Hauptverfasser:	Barkhausen, Franziska, Laura Ares Santos, Schumacher, Stefan, Sperling, Jan
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Sprache:	eng
Schlagworte:	Context Correlation Degrees of freedom Elementary excitations Fermions Hybrid modes Quantum entanglement Quantum phenomena Subsystems
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creator	Barkhausen, Franziska Laura Ares Santos Schumacher, Stefan Sperling, Jan
description	Common notions of entanglement are based on well-separated subsystems. However, obtaining such independent degrees of freedom is not always possible because of physical constraints. In this work, we explore the notion of entanglement in the context of dependent degrees of freedom. As a physically relevant application, we specifically study quantum correlation features for quasi-particle descriptions. Those are paramount for interacting light-matter systems, utilizing excitations of fermion-boson hybrid modes. By comparing independent and dependent degrees of freedom, we uncover that certain states are non-entangled although they would be entangled when only focusing on the common, independent description, and vice versa. Therefore, new insight is provided into the resourcefulness of quantum correlations within the rarely discussed context of dependent degrees of freedom for light-matter links in quantum information applications.
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subjects	Context Correlation Degrees of freedom Elementary excitations Fermions Hybrid modes Quantum entanglement Quantum phenomena Subsystems
title	Entanglement between dependent degrees of freedom: Quasi-particle correlations
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