Algebraic cutting equations
Copyright policy )Algebraic cutting equations
The cutting equations are diagrammatic identities that are used to prove perturbative unitarity in quantum field theory. In this paper, we derive algebraic, upgraded versions of them. Differently from the diagrammatic versions, the algebraic identities also holds for propagators with arbitrary, nonvanishing widths. In particular, the cut propagators do not need to vanish off shell. The new approach provides a framework to address unsolved problems of perturbative quantum field theory and a tool to investigate perturbative unitarity in higher-derivative theories that are relevant to the problem of quantum gravity, such as the Lee-Wick models and the fakeon models.
33 pages, 16 figures; v2: minor changes, Ann. Phys
- University of Pisa Italy
High Energy Physics - Theory, perturbative expansion, FOS: Physical sciences, symmetries, Mathematical Physics (math-ph), Perturbative methods of renormalization applied to problems in quantum field theory, renormalization, Perturbative expansion; Quantum field theory; Quantum gravity; Renormalization; Symmetries; Unitarity, High Energy Physics - Theory (hep-th), quantum gravity, unitarity, quantum field theory, Feynman diagrams, Mathematical Physics
High Energy Physics - Theory, perturbative expansion, FOS: Physical sciences, symmetries, Mathematical Physics (math-ph), Perturbative methods of renormalization applied to problems in quantum field theory, renormalization, Perturbative expansion; Quantum field theory; Quantum gravity; Renormalization; Symmetries; Unitarity, High Energy Physics - Theory (hep-th), quantum gravity, unitarity, quantum field theory, Feynman diagrams, Mathematical Physics
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