Asymptotic Completeness in a Class of Massive Wedge-Local Quantum Field Theories in any Dimension

Asymptotic Completeness in a Class of Massive Wedge-Local Quantum Field Theories in any Dimension

A recently developed n -particle scattering theory for wedge-local quantum field theories is applied to a class of models described and constructed by Grosse, Lechner, Buchholz, and Summers. In the BLS-deformation setting we establish explicit expressions for n -particle wave operators and the S -ma...

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Veröffentlicht in:Communications in mathematical physics 2023-08, Vol.401 (3), p.2355-2390
Hauptverfasser: Duell, Maximilian, Dybalski, Wojciech
Format: Artikel
Sprache:eng
Schlagworte:
Asymptotic properties
Classical and Quantum Gravitation
Completeness
Complex Systems
Deformation
Mathematical and Computational Physics
Mathematical Physics
Operators (mathematics)
Physics
Physics and Astronomy
Quantum Physics
Quantum theory
Relativity
Relativity Theory
S matrix theory
Theoretical
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Zusammenfassung:A recently developed n -particle scattering theory for wedge-local quantum field theories is applied to a class of models described and constructed by Grosse, Lechner, Buchholz, and Summers. In the BLS-deformation setting we establish explicit expressions for n -particle wave operators and the S -matrix of ordered asymptotic states, and we show that ordered asymptotic completeness is stable under the general BLS-deformation construction. In particular, the (ordered) Grosse–Lechner S -matrices are non-trivial also beyond two-particle scattering and factorize into 2-particle scattering processes, which is an unusual feature in space-time dimension d > 1 + 1 . Most notably, the Grosse–Lechner models provide the first examples of relativistic (wedge-local) QFT in space-time dimension  d > 1 + 1 which are interacting and asymptotically complete.
ISSN:0010-3616
1432-0916
DOI:10.1007/s00220-023-04690-0