Scaling Algebras and Renormalization Group in Algebraic Quantum Field Theory.

The concept of scaling algebra provides a novel framework for the general structural analysis and classification of the short distance properties of algebras of local observables in relativistic quantum field theory. In the present article this method is applied to the simple example of massive free field theory in s=1,2 and 3 spatial dimensions. Not quite unexpectedly, one obtains for s=2,3 in the scaling (short distance) limit the algebra of local observables in massless free field theory. The case s=1 offers, however, some surprises. There the algebra of observables acquires in the scaling limit a non-trivial center and describes charged physical states satisfying Gauss' law. The latter result is of relevance for the interpretation of the Schwinger model at short distances and illustrates the conceptual and computational virtues of the method.

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RELATIVISTIC QUANTUM FIELD THEORY FOR CONDENSED SYSTEMS (II): RENORMALIZATION PROCEDURE

International Journal of Modern Physics B ◽

10.1142/s0217979203023057 ◽

2003 ◽

Vol 17 (30) ◽

pp. 5713-5723 ◽

Cited By ~ 1

Author(s):

HIROYUKI MATSUURA

Keyword(s):

Field Theory ◽

Quantum Field Theory ◽

Electric Charge ◽

Relativistic Quantum ◽

Free Field ◽

Mass Shift ◽

Quantum Field ◽

Relativistic Quantum Field Theory ◽

Self Energy ◽

Physical Mass

We proposed Atomic Schwinger–Dyson method (ASD method) in previous paper, which was a nonperturbative and relativistic quantum field theory for a finite baryon density. We think it is important to show the significance of renormarization in order to get real physical predictions. Moreover, the real value of physical mass, electric charge and wave function are completely different from those of the non-renormalized electron and photon in mean field theory, since there are many of the particle-antiparticle creations and annihilations, particle-hole excitation, and Pauli blocking, which give an effect on bare mass, electric charge, polarization of vacuum, and self-energy. In this paper, we shows that ASD method is renormalizable theory, and that photon condensation of ASD method gave rise to Coulomb's potential and the mass shift of electron. The interacting photon and electron fields, which have physical mass and electric charge, are expressed as generalized free field equations by using the mass shift and the self-energy of those particles. We obtain the expression of an exact solution of these particles on the basis of the Green functional method.

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PHASE SPACE PROPERTIES OF CHARGED FIELDS IN THEORIES OF LOCAL OBSERVABLES

Reviews in Mathematical Physics ◽

10.1142/s0129055x95000219 ◽

1995 ◽

Vol 07 (04) ◽

pp. 527-557 ◽

Cited By ~ 6

Author(s):

D. BUCHHOLZ ◽

C. D’ANTONI

Keyword(s):

Field Theory ◽

Quantum Field Theory ◽

Phase Space ◽

Quantum Field ◽

Algebraic Quantum Field Theory ◽

Space Analysis ◽

Algebraic Quantum ◽

Thermal Features ◽

Local Observables

Within the setting of algebraic quantum field theory a relation between phase-space properties of observables and charged fields is established. These properties are expressed in terms of compactness and nuclearity conditions which are the basis for the characterization of theories with physically reasonable causal and thermal features. Relevant concepts and results of phase space analysis in algebraic quantum field theory are reviewed and the underlying ideas are outlined.

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CAUSAL SPACES, CAUSAL COMPLEMENTS AND THEIR RELATIONS TO QUANTUM FIELD THEORY

Reviews in Mathematical Physics ◽

10.1142/s0129055x96000093 ◽

1996 ◽

Vol 08 (02) ◽

pp. 229-270 ◽

Cited By ~ 6

Author(s):

MICHAEL KEYL

Keyword(s):

Field Theory ◽

Quantum Field Theory ◽

Causal Structure ◽

Space Time ◽

Quantum Field ◽

Algebraic Quantum ◽

Space Time Structure ◽

Klein Gordon ◽

Free Scalar ◽

Local Observables

In this paper the question is analyzed, how it is possilble to reconstruct classical spacetime from the net of local observables of a quantum field theory. To this end different aspects of space-time structure are considered separately. Special attention is drawn to the topological and the causal structure of space-time. Within the scope of causality the differences between causal spaces introduced by Kronheimer and Penrose and causal disjointness relations used in algebraic quantum field theory are considered. Finally we show that the free scalar field on a globally hyperbolic space-time is a special example for our scheme, even if the corresponding Klein-Gordon operator is a Huygens operator.

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Relating Nets and Factorization Algebras of Observables: Free Field Theories

Communications in Mathematical Physics ◽

10.1007/s00220-019-03652-9 ◽

2020 ◽

Vol 373 (1) ◽

pp. 107-174 ◽

Cited By ~ 2

Author(s):

Owen Gwilliam ◽

Kasia Rejzner

Keyword(s):

Field Theory ◽

Quantum Field Theory ◽

Equations Of Motion ◽

Free Field ◽

Intermediate Step ◽

Quantum Field ◽

Associative Algebras ◽

Main Claim ◽

Algebraic Quantum ◽

Factorization Algebras

AbstractIn this paper we relate two mathematical frameworks that make perturbative quantum field theory rigorous: perturbative algebraic quantum field theory (pAQFT) and the factorization algebras framework developed by Costello and Gwilliam. To make the comparison as explicit as possible, we use the free scalar field as our running example, while giving proofs that apply to any field theory whose equations of motion are Green-hyperbolic (which includes, for instance, free fermions). The main claim is that for such free theories, there is a natural transformation intertwining the two constructions. In fact, both approaches encode equivalent information if one assumes the time-slice axiom. The key technical ingredient is to use time-ordered products as an intermediate step between a net of associative algebras and a factorization algebra.

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Quantum mechanics

10.1093/oso/9780198802877.003.0002 ◽

2018 ◽

Author(s):

Michael Kachelriess

Keyword(s):

Field Theory ◽

Quantum Field Theory ◽

Quantum Mechanics ◽

Relativistic Quantum ◽

Transition Amplitude ◽

External Source ◽

Quantum Field ◽

Damping Term ◽

Relativistic Quantum Theory ◽

Generating Functional

After a brief review of the operator approach to quantum mechanics, Feynmans path integral, which expresses a transition amplitude as a sum over all paths, is derived. Adding a linear coupling to an external source J and a damping term to the Lagrangian, the ground-state persistence amplitude is obtained. This quantity serves as the generating functional Z[J] for n-point Green functions which are the main target when studying quantum field theory. Then the harmonic oscillator as an example for a one-dimensional quantum field theory is discussed and the reason why a relativistic quantum theory should be based on quantum fields is explained.

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