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Classification of primary constraints for new general relativity in the premetric approach

María-José Guzmán, Shymaa Khaled Ibraheem

2021International Journal of Geometric Methods in Modern Physics15 citationsDOIOpen Access PDF

Abstract

We introduce a novel procedure for studying the Hamiltonian formalism of new general relativity (NGR) based on the mathematical properties encoded in the constitutive tensor defined by the premetric approach. We derive the canonical momenta conjugate to the tetrad field and study the eigenvalues of the Hessian tensor, which is mapped to a Hessian matrix with the help of indexation formulas. The properties of the Hessian matrix heavily rely on the possible values of the free coefficients [Formula: see text] appearing in the NGR Lagrangian. We find four null eigenvalues associated with trivial primary constraints in the temporal part of the momenta. The remaining eigenvalues are grouped in four sets, which have multiplicity 3, 1, 5 and 3, and can be set to zero depending on different choices of the coefficients [Formula: see text]. There are nine possible different cases when one, two, or three sets of eigenvalues are imposed to vanish simultaneously. All cases lead to a different number of primary constraints, which are consistent with previous work on the Hamiltonian analysis of NGR by Blixt et al. (2018).

Topics & Concepts

Hessian matrixEigenvalues and eigenvectorsTetradGeneral relativityMathematicsHamiltonian (control theory)Pure mathematicsCurvatureApplied mathematicsInvertible matrixGeneral theoryCanonical formFormalism (music)Mathematical physicsEinstein field equationsMathematical analysisMatrix (chemical analysis)Tensor (intrinsic definition)PhysicsHamiltonian mechanicsSymmetric matrixPulsars and Gravitational Waves ResearchAstrophysical Phenomena and ObservationsNoncommutative and Quantum Gravity Theories
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