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Hauptverfasser: Blasone, Massimo, De Siena, Silvio, Lambiase, Gaetano, Matrella, Cristina, Micciola, Bruno
Format: Preprint
Veröffentlicht: 2024
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2402.09195
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author Blasone, Massimo
De Siena, Silvio
Lambiase, Gaetano
Matrella, Cristina
Micciola, Bruno
author_facet Blasone, Massimo
De Siena, Silvio
Lambiase, Gaetano
Matrella, Cristina
Micciola, Bruno
contents We exploit the complete complementarity relations (CCR) to fully characterize various aspects of quantumness in QED scattering processes at tree level. As a paradigmatic example, we consider Bhabha scattering in two different configurations: in the first case, the initial state is factorized in the spin and we study the generation of entanglement due to the scattering. Then we consider the most general case in which the initial state can be entangled: we find that the scattering generates and distributes quantum information in a non-trivial way among the spin degrees of freedom of the particles, with CCR relations being preserved. An important outcome of our analysis is that maximal entanglement is conserved in the scattering process involving only fermions as input and output states, with a more complex situation if photons are present.
format Preprint
id arxiv_https___arxiv_org_abs_2402_09195
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Complete complementarity relations in tree level QED processes
Blasone, Massimo
De Siena, Silvio
Lambiase, Gaetano
Matrella, Cristina
Micciola, Bruno
Quantum Physics
High Energy Physics - Phenomenology
High Energy Physics - Theory
We exploit the complete complementarity relations (CCR) to fully characterize various aspects of quantumness in QED scattering processes at tree level. As a paradigmatic example, we consider Bhabha scattering in two different configurations: in the first case, the initial state is factorized in the spin and we study the generation of entanglement due to the scattering. Then we consider the most general case in which the initial state can be entangled: we find that the scattering generates and distributes quantum information in a non-trivial way among the spin degrees of freedom of the particles, with CCR relations being preserved. An important outcome of our analysis is that maximal entanglement is conserved in the scattering process involving only fermions as input and output states, with a more complex situation if photons are present.
title Complete complementarity relations in tree level QED processes
topic Quantum Physics
High Energy Physics - Phenomenology
High Energy Physics - Theory
url https://arxiv.org/abs/2402.09195