Jorge Romero scite author profile

We present a manifestly Lorentz-covariant description of the phase space of general relativity with the Immirzi parameter. This formulation emerges after solving the second-class constraints arising in the canonical analysis of the Holst action. We show that the new canonical variables give rise to other Lorentz-covariant parametrizations of the phase space via canonical transformations. The resulting form of the first-class constraints in terms of new variables is given. In the time gauge, these variables and the constraints become those found by Barbero.

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Barbero’s formulation from aBF-type action with the Immirzi parameter

Celada

Montesinos

Romero

2016

Class. Quantum Grav.

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Abstract.Starting from a constrained real BF-type action for general relativity that includes both the Immirzi parameter and the cosmological constant, we obtain the Ashtekar-Barbero variables used in the canonical approach to the quantization of the gravitational field. This is accomplished by explicitly solving the second-class constraints resulting from the Hamiltonian analysis of the considered action, and later imposing the time gauge. All throughout this work the tetrad formalism is left aside, obtaining the Ashtekar-Barbero variables entirely in terms of the B-fields that define the action.

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Canonical analysis of Holst action without second-class constraints

2020

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We perform the canonical analysis of the Holst action for general relativity with a cosmological constant without introducing second-class constraints. Our approach consists in identifying the dynamical and nondynamical parts of the involved variables from the very outset. After eliminating the nondynamical variables associated with the connection, we obtain the description of phase space in terms of manifestly SO(3, 1) [or SO(4), depending on the signature] covariant canonical variables and first-class constraints only. We impose the time gauge on them and show that the Ashtekar-Barbero formulation of general relativity emerges. Later, we discuss a family of canonical transformations that allows us to construct new SO(3, 1) [or SO(4)] covariant canonical variables for the phase space of the theory and compare them with the ones already reported in the literature, pointing out the presence of a set of canonical variables not considered before. Finally, we resort to the time gauge again and find that the theory, when written in terms of the new canonical variables, either collapses to the SO(3) ADM formalism or to the Ashtekar-Barbero formalism with a rescaled Immirzi parameter.

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Canonical analysis ofn-dimensional Palatini action without second-class constraints

et al. 2020

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We carry out the canonical analysis of the n-dimensional Palatini action with or without a cosmological constant (n ≥ 3) introducing neither second-class constraints nor resorting to any gauge fixing. This is accomplished by providing an expression for the spatial components of the connection that allows us to isolate the nondynamical variables present among them, which can later be eliminated from the action by using their own equation of motion. As a result, we obtain the description of the phase space of general relativity in terms of manifestly SO(n − 1, 1) [or SO(n)] covariant variables subject to first-class constraints only, with no second-class constraints arising during the process. Afterwards, we perform, at the covariant level, a canonical transformation to a set of variables in terms of which the above constraints take a simpler form. Finally, we impose the time gauge and make contact with the SO(n − 1) ADM formalism.I.

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SU(1,1) Barbero-like variables derived from Holst action

et al. 2018

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We work on a spacetime manifold foliated by timelike leaves. In this setting, we explore the solution of the second-class constraints arising during the canonical analysis of the Holst action with a cosmological constant. The solution is given in a manifestly Lorentz-covariant fashion, and the resulting canonical formulation is expressed using several sets of real variables that are related to one another by canonical transformations. By applying a gauge fixing to this formulation, we obtain a description of gravity as an SU (1, 1) gauge theory that resembles the Ashtekar-Barbero formulation.I. * merced@fis.cinvestav.mx † ljromero@fis.cinvestav.mx ‡ rescobedo@fis.cinvestav.mx § mcelada@fis.cinvestav.mx 1 It however manifests off shell in the classical theory. See Ref. [8].

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Jorge Romero

Manifestly Lorentz-covariant variables for the phase space of general relativity

Barbero’s formulation from aBF-type action with the Immirzi parameter

Canonical analysis of Holst action without second-class constraints

Canonical analysis ofn-dimensional Palatini action without second-class constraints

SU(1,1) Barbero-like variables derived from Holst action

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