Entanglement entropy in particle decay

A bstract The decay of a parent particle into two or more daughter particles results in an entangled quantum state as a consequence of conservation laws in the decay process. Recent experiments at Belle and BaBar take advantage of quantum entanglement and the correlations in the time evolution of th...

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Veröffentlicht in:	The journal of high energy physics 2013-11, Vol.2013 (11), p.1-26, Article 116
Hauptverfasser:	Lello, Louis, Boyanovsky, Daniel, Holman, Richard
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Sprache:	eng
Schlagworte:	Classical and Quantum Gravitation Correlation analysis Decomposition Density Elementary Particles Entanglement Entropy Evolution High energy physics Mathematical analysis Parents Physics Physics and Astronomy Quantum Field Theories Quantum Field Theory Quantum Physics Relativity Theory String Theory
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creator	Lello, Louis Boyanovsky, Daniel Holman, Richard
description	A bstract The decay of a parent particle into two or more daughter particles results in an entangled quantum state as a consequence of conservation laws in the decay process. Recent experiments at Belle and BaBar take advantage of quantum entanglement and the correlations in the time evolution of the product particles to study CP and T violations. If one (or more) of the product particles are not observed, their degrees of freedom are traced out of the pure state density matrix resulting from the decay, leading to a mixed state density matrix and an entanglement entropy. This entropy is a measure of the loss of information present in the original quantum correlations of the entangled state. We use the Wigner-Weisskopf method to construct an approximation to this state that evolves in time in a manifestly unitary way. We then obtain the entanglement entropy from the reduced density matrix of one of the daughter particles obtained by tracing out the unobserved states, and follow its time evolution. We find that it grows over a time scale determined by the lifetime of the parent particle to a maximum, which when the width of the parent particle is narrow, describes the phase space distribution of maximally entangled Bell-like states. The method is generalized to the case in which the parent particle is described by a wave packet localized in space. Possible experimental avenues to measure the entanglement entropy in the decay of mesons at rest are discussed.
doi_str_mv	10.1007/JHEP11(2013)116
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We then obtain the entanglement entropy from the reduced density matrix of one of the daughter particles obtained by tracing out the unobserved states, and follow its time evolution. We find that it grows over a time scale determined by the lifetime of the parent particle to a maximum, which when the width of the parent particle is narrow, describes the phase space distribution of maximally entangled Bell-like states. The method is generalized to the case in which the parent particle is described by a wave packet localized in space. 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subjects	Classical and Quantum Gravitation Correlation analysis Decomposition Density Elementary Particles Entanglement Entropy Evolution High energy physics Mathematical analysis Parents Physics Physics and Astronomy Quantum Field Theories Quantum Field Theory Quantum Physics Relativity Theory String Theory
title	Entanglement entropy in particle decay
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