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(Top) 1 Analytic approaches 1.1 Wightman axioms 1.2 Osterwalder–Schrader axioms 1.3 Haag–Kastler axioms 1.4 Euclidean CFT axioms 2 See also 3 References

Axiomatic quantum field theory

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Axiomatic quantum field theory is a mathematical discipline which aims to describe quantum field theory in terms of rigorous axioms. It is strongly associated with functional analysis and operator algebras, but has also been studied in recent years from a more geometric and functorial perspective.

There are two main challenges in this discipline. First, one must propose a set of axioms which describe the general properties of any mathematical object that deserves to be called a "quantum field theory". Then, one gives rigorous mathematical constructions of examples satisfying these axioms.

Analytic approaches

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Wightman axioms

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The first set of axioms for quantum field theories, known as the Wightman axioms, were proposed by Arthur Wightman in the early 1950s. These axioms attempt to describe QFTs on flat Minkowski spacetime by regarding quantum fields as operator-valued distributions acting on a Hilbert space. In practice, one often uses the Wightman reconstruction theorem, which guarantees that the operator-valued distributions and the Hilbert space can be recovered from the collection of correlation functions.

Osterwalder–Schrader axioms

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The correlation functions of a QFT satisfying the Wightman axioms often can be analytically continued from Lorentz signaturetoEuclidean signature. (Crudely, one replaces the time variable $\;t\;$ with imaginary time $\;\tau =-{\sqrt {-1\,}}\,t~;$ the factors of $\;{\sqrt {-1\,}}\;$ change the sign of the time-time components of the metric tensor.) The resulting functions are called Schwinger functions. For the Schwinger functions there is a list of conditions — analyticity, permutation symmetry, Euclidean covariance, and reflection positivity — which a set of functions defined on various powers of Euclidean space-time must satisfy in order to be the analytic continuation of the set of correlation functions of a QFT satisfying the Wightman axioms.

Haag–Kastler axioms

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The Haag–Kastler axioms axiomatize QFT in terms of nets of algebras.

Euclidean CFT axioms

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These axioms (see e.g.^[1]) are used in the conformal bootstrap approach to conformal field theoryin $\mathbb {R} ^{d}$ . They are also referred to as Euclidean bootstrap axioms.

References

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^ Kravchuk, Petr; Qiao, Jiaxin; Rychkov, Slava (2021-04-05). "Distributions in CFT II. Minkowski Space". arXiv:2104.02090v1 [hep-th].

Streater, R. F.; Wightman, A. S. (1964). PCT, Spin and Statistics, and All That. New York: W. A. Benjamin. OCLC 930068.
Bogoliubov, N.; Logunov, A.; Todorov, I. (1975). Introduction to Axiomatic Quantum Field Theory. Reading, Massachusetts: W. A. Benjamin. OCLC 1527225.
Araki, H. (1999). Mathematical Theory of Quantum Fields. Oxford University Press. ISBN 0-19-851773-4.

Quantum field theories

Theories

Models

Regular	Born–Infeld Euler–Heisenberg Ginzburg–Landau Non-linear sigma Proca Quantum electrodynamics Quantum chromodynamics Quartic interaction Scalar electrodynamics Scalar chromodynamics Soler Yang–Mills Yang–Mills–Higgs Yukawa
Low dimensional	2D Yang–Mills Bullough–Dodd Gross–Neveu Schwinger Sine-Gordon Thirring Thirring–Wess Toda
Conformal	2D free massless scalar Liouville Minimal Polyakov Wess–Zumino–Witten
Supersymmetric	4D N = 1 N = 1 super Yang–Mills Seiberg–Witten Super QCD Wess–Zumino
Superconformal	6D (2,0) ABJM N = 4 super Yang–Mills
Supergravity	4D N = 1 4D N = 8 11D Higher dimensional Pure 4D N = 1
Topological	BF Chern–Simons
Particle theory	Chiral Fermi MSSM Nambu–Jona-Lasinio NMSSM Standard Model Stueckelberg

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