Entanglement of conceptual entities in Quantum Model Theory (QMod)

Diederik Aerts; Sandro Sozzo

Entanglement of conceptual entities in Quantum Model Theory (QMod)

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We have recently elaborated 'Quantum Model Theory' (QMod) to model situations where the quantum effects of contextuality, interference, superposition, entanglement and emergence, appear without the entities giving rise to these situations having necessarily to be of microscopic nature. We have shown that QMod models without introducing linearity for the set of the states. In this paper we prove that QMod, although not using linearity for the state space, provides a method of identification for entangled states and an intuitive explanation for their occurrence. We illustrate this method for entanglement identification with concrete examples.

Originele taal-2	English
Titel	Quantum Interaction
Redacteuren	J.R. Busemeyer, F. Dubois, A. Lambert-Mogiliansky, M. Melucci
Plaats van productie	Berlin
Uitgeverij	Springer
Pagina's	114-125
Aantal pagina's	12
ISBN van geprinte versie	978-3-642-35658-2
Status	Published - 2012

Publicatie series

Naam	Theoretical Computer Science and General Issues
Uitgeverij	Springer
Volume	7620

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http://arxiv.org/abs/1204.4901

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AB - We have recently elaborated 'Quantum Model Theory' (QMod) to model situations where the quantum effects of contextuality, interference, superposition, entanglement and emergence, appear without the entities giving rise to these situations having necessarily to be of microscopic nature. We have shown that QMod models without introducing linearity for the set of the states. In this paper we prove that QMod, although not using linearity for the state space, provides a method of identification for entangled states and an intuitive explanation for their occurrence. We illustrate this method for entanglement identification with concrete examples.

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KW - concept theory

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KW - entanglement

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Entanglement of conceptual entities in Quantum Model Theory (QMod)

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