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The quantum gauge principle

We consider the evolution of quantum fields on a classical background space-time, formulated in the language of differential geometry. Time evolution along the worldlines of observers is described by parallel transport operators in an infinite-dimensional vector bundle over the space-time manifold....

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Autor principal: Graudenz, Dirk
Lenguaje:eng
Publicado: 1996
Materias:
Acceso en línea:http://cds.cern.ch/record/302069
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author Graudenz, Dirk
author_facet Graudenz, Dirk
author_sort Graudenz, Dirk
collection CERN
description We consider the evolution of quantum fields on a classical background space-time, formulated in the language of differential geometry. Time evolution along the worldlines of observers is described by parallel transport operators in an infinite-dimensional vector bundle over the space-time manifold. The time evolution equation and the dynamical equations for the matter fields are invariant under an arbitrary local change of frames along the restriction of the bundle to the worldline of an observer, thus implementing a ``quantum gauge principle''. We derive dynamical equations for the connection and a complex scalar quantum field based on a gauge field action. In the limit of vanishing curvature of the vector bundle, we recover the standard equation of motion of a scalar field in a curved background space-time.
id cern-302069
institution Organización Europea para la Investigación Nuclear
language eng
publishDate 1996
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spelling cern-3020692023-03-14T20:10:49Zhttp://cds.cern.ch/record/302069engGraudenz, DirkThe quantum gauge principleParticle Physics - TheoryWe consider the evolution of quantum fields on a classical background space-time, formulated in the language of differential geometry. Time evolution along the worldlines of observers is described by parallel transport operators in an infinite-dimensional vector bundle over the space-time manifold. The time evolution equation and the dynamical equations for the matter fields are invariant under an arbitrary local change of frames along the restriction of the bundle to the worldline of an observer, thus implementing a ``quantum gauge principle''. We derive dynamical equations for the connection and a complex scalar quantum field based on a gauge field action. In the limit of vanishing curvature of the vector bundle, we recover the standard equation of motion of a scalar field in a curved background space-time.We consider the evolution of quantum fields on a classical background space-time, formulated in the language of differential geometry. Time evolution along the worldlines of observers is described by parallel transport operators in an infinite-dimensional vector bundle over the space-time manifold. The time evolution equation and the dynamical equations for the matter fields are invariant under an arbitrary local change of frames along the restriction of the bundle to the worldline of an observer, thus implementing a ``quantum gauge principle''. We derive dynamical equations for the connection and a complex scalar quantum field based on a gauge field action. In the limit of vanishing curvature of the vector bundle, we recover the standard equation of motion of a scalar field in a curved background space-time.hep-th/9604180CERN-TH-96-107CERN-TH-96-107oai:cds.cern.ch:3020691996-04-29
spellingShingle Particle Physics - Theory
Graudenz, Dirk
The quantum gauge principle
title The quantum gauge principle
title_full The quantum gauge principle
title_fullStr The quantum gauge principle
title_full_unstemmed The quantum gauge principle
title_short The quantum gauge principle
title_sort quantum gauge principle
topic Particle Physics - Theory
url http://cds.cern.ch/record/302069
work_keys_str_mv AT graudenzdirk thequantumgaugeprinciple
AT graudenzdirk quantumgaugeprinciple