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Field Current Identities and Algebra of Fields

It is shown that the possible identity between the various hadronic current operators and the corresponding spin-1 meson field operators determines the general structure of the hadronic part of the total Lagrangian. In particular, the identity between the isovector electromagnetic current and the ne...

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Detalles Bibliográficos
Autores principales: Lee, T D, Zumino, B
Lenguaje:eng
Publicado: 1967
Materias:
Acceso en línea:https://dx.doi.org/10.1103/PhysRev.163.1667
http://cds.cern.ch/record/2867725
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author Lee, T D
Zumino, B
author_facet Lee, T D
Zumino, B
author_sort Lee, T D
collection CERN
description It is shown that the possible identity between the various hadronic current operators and the corresponding spin-1 meson field operators determines the general structure of the hadronic part of the total Lagrangian. In particular, the identity between the isovector electromagnetic current and the neutral ρ-meson field implies that the ρ dependence of the strong interaction must be the same as that in the Yang-Mills theory, except for the mass term of the ρ meson. The explicit form of the interaction Lagrangian makes possible a general study of the local equal-time commutators of the various hadronic current operators, including the effects of the electromagnetic interaction. Many of these electromagnetic correction terms depend only on the general requirement of gauge invariance, and are independent of whether the proposed field-current identities are valid or not. For example, the usual Schwinger term λ(∂∂rj)δ3(r−r′) in the commutator between the time component of any charged hadronic weak interaction current and the jth space component of its Hermitian conjugate should be replaced by λ[(∂∂rj)+ieAj]δ3(r−r′), where Aj is the electromagnetic field operator. The contribution of such a correction term, i.e., λieAjδ3(r−r′), remains present in the integrated form of the commutator. In the usual current algebra, λ is mathematically undefined. If field-current identities hold, then these current commutators are the same as the corresponding algebra of the field operators, and λ becomes a well-defined c number. Some speculative remarks concerning the possible extension of the algebra of fields to the lepton currents are presented.
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spelling cern-28677252023-08-31T14:20:02Zdoi:10.1103/PhysRev.163.1667http://cds.cern.ch/record/2867725engLee, T DZumino, BField Current Identities and Algebra of FieldsParticle Physics - PhenomenologyIt is shown that the possible identity between the various hadronic current operators and the corresponding spin-1 meson field operators determines the general structure of the hadronic part of the total Lagrangian. In particular, the identity between the isovector electromagnetic current and the neutral ρ-meson field implies that the ρ dependence of the strong interaction must be the same as that in the Yang-Mills theory, except for the mass term of the ρ meson. The explicit form of the interaction Lagrangian makes possible a general study of the local equal-time commutators of the various hadronic current operators, including the effects of the electromagnetic interaction. Many of these electromagnetic correction terms depend only on the general requirement of gauge invariance, and are independent of whether the proposed field-current identities are valid or not. For example, the usual Schwinger term λ(∂∂rj)δ3(r−r′) in the commutator between the time component of any charged hadronic weak interaction current and the jth space component of its Hermitian conjugate should be replaced by λ[(∂∂rj)+ieAj]δ3(r−r′), where Aj is the electromagnetic field operator. The contribution of such a correction term, i.e., λieAjδ3(r−r′), remains present in the integrated form of the commutator. In the usual current algebra, λ is mathematically undefined. If field-current identities hold, then these current commutators are the same as the corresponding algebra of the field operators, and λ becomes a well-defined c number. Some speculative remarks concerning the possible extension of the algebra of fields to the lepton currents are presented.CERN-PRE-7379aoai:cds.cern.ch:28677251967
spellingShingle Particle Physics - Phenomenology
Lee, T D
Zumino, B
Field Current Identities and Algebra of Fields
title Field Current Identities and Algebra of Fields
title_full Field Current Identities and Algebra of Fields
title_fullStr Field Current Identities and Algebra of Fields
title_full_unstemmed Field Current Identities and Algebra of Fields
title_short Field Current Identities and Algebra of Fields
title_sort field current identities and algebra of fields
topic Particle Physics - Phenomenology
url https://dx.doi.org/10.1103/PhysRev.163.1667
http://cds.cern.ch/record/2867725
work_keys_str_mv AT leetd fieldcurrentidentitiesandalgebraoffields
AT zuminob fieldcurrentidentitiesandalgebraoffields