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Main Author: Rodríguez-Tzompantzi, Omar
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2604.19109
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author Rodríguez-Tzompantzi, Omar
author_facet Rodríguez-Tzompantzi, Omar
contents We develop a systematic Hamiltonian formulation for a gravitating topological matter system in three-dimensional spacetime, coupling a scalar gauge field and a rank-2 antisymmetric gauge field to Einstein--Cartan gravity. We perform the Dirac--Bergmann analysis, systematically finding the full structure of the constraints, classifying them into first- and second-class ones, and computing their Poisson bracket algebra. Furthermore, we write down the explicit expression for the Hamiltonian generator of gauge symmetries on the full set of canonical variables, containing the exact number of gauge parameters, and demonstrate that, through a mapping of the gauge parameters, these gauge transformations reproduce on-shell the spacetime diffeomorphism and local Poincaré symmetries, thereby establishing the full symmetry structure of the coupled model. Our canonical analysis further reveals that the reduced phase-space admits exactly three reducibility conditions for the first-class constraints, which guarantee the consistency of the gravitating matter system by ensuring a correct count of physical degrees of freedom. The fundamental symplectic structure on the reduced phase-space is established through the explicit computation of the Dirac brackets.
format Preprint
id arxiv_https___arxiv_org_abs_2604_19109
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Hamiltonian formulation for scalar and two-form gauge fields coupled to 3d gravity
Rodríguez-Tzompantzi, Omar
High Energy Physics - Theory
Mathematical Physics
We develop a systematic Hamiltonian formulation for a gravitating topological matter system in three-dimensional spacetime, coupling a scalar gauge field and a rank-2 antisymmetric gauge field to Einstein--Cartan gravity. We perform the Dirac--Bergmann analysis, systematically finding the full structure of the constraints, classifying them into first- and second-class ones, and computing their Poisson bracket algebra. Furthermore, we write down the explicit expression for the Hamiltonian generator of gauge symmetries on the full set of canonical variables, containing the exact number of gauge parameters, and demonstrate that, through a mapping of the gauge parameters, these gauge transformations reproduce on-shell the spacetime diffeomorphism and local Poincaré symmetries, thereby establishing the full symmetry structure of the coupled model. Our canonical analysis further reveals that the reduced phase-space admits exactly three reducibility conditions for the first-class constraints, which guarantee the consistency of the gravitating matter system by ensuring a correct count of physical degrees of freedom. The fundamental symplectic structure on the reduced phase-space is established through the explicit computation of the Dirac brackets.
title Hamiltonian formulation for scalar and two-form gauge fields coupled to 3d gravity
topic High Energy Physics - Theory
Mathematical Physics
url https://arxiv.org/abs/2604.19109