Covariant quantization of gauge theories with Lagrange multipliers

We revisited the equivalence between the second- and first-order formulations of the Yang-Mills and gravity using the path integral formalism. We demonstrated that structural identities can be derived to relate Green\'s functions of auxiliary fields, computed in the first-order formulation, to...

ver descrição completa

Detalhes bibliográficos
Autor: Martins Filho, Sérgio
Formato: tesis doctoral
Estado:Versión publicada
Fecha de publicación:2024
País:Brasil
Recursos:Universidade de São Paulo (USP)
Repositorio:Biblioteca Digital de Teses e Dissertações da USP
Idioma:inglés
OAI Identifier:oai:teses.usp.br:tde-19122024-130256
Acesso em linha:https://www.teses.usp.br/teses/disponiveis/43/43134/tde-19122024-130256/
Access Level:acceso abierto
Palavra-chave:Equivalência quântica
First-Order formulation
Formulação de primeira ordem
Gravitação
Gravity
Lagrange multiplier
Multiplicador de Lagrange
Quantum equivalence
Teoria de Yang-Mills
Yang-Mills theory
Descrição
Resumo:We revisited the equivalence between the second- and first-order formulations of the Yang-Mills and gravity using the path integral formalism. We demonstrated that structural identities can be derived to relate Green\'s functions of auxiliary fields, computed in the first-order formulation, to Green\'s functions of composite fields in the second-order formulation. In Yang-Mills theory, these identities can be verified at the integrand level of the loop integrals. For gravity, the path integral was obtained through the Faddeev-Senjanovic procedure. The Senjanovic determinant plays a key role in canceling tadpole-like contributions, which vanish in the dimensional regularization scheme but persist at finite temperature. Thus, the equivalence between the two formalisms is maintained at finite temperature. We also studied the coupling to matter. In Yang-Mills theory, we investigated both minimal and non-minimal couplings. We derived first-order formulations, equivalent to the respective second-order formulations, by employing a procedure that introduces Lagrange multipliers. This procedure can be easily generalized to gravity. We also considered an alternative gravity model, which is both renormalizable and unitary, that uses Lagrange multipliers to restrict the loop expansion to one-loop order. However, this approach leads to a doubling of one-loop contributions due to the additional degrees of freedom associated with Ostrogradsky instabilities. To address this, we proposed a modified formalism that resolves these issues by requiring the path integral to be invariant under field redefinitions. This introduces ghost fields responsible for canceling the extra one-loop contributions arising from the Lagrange multiplier fields, while also removing unphysical degrees of freedom. We also demonstrated that the modified formalism and the Faddeev-Popov procedure commute, indicating that the Lagrange multipliers can be viewed as purely quantum fields.