Multisymplectic unified formalism for Einstein-Hilbert gravity

Gaset, Jordi; Román‐Roy, Narciso

doi:10.1063/1.4998526

Cited by 32 publications

(41 citation statements)

References 45 publications

(153 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The present work continues the exploration of geometrical formulations of the Lagrangian and Hamiltonian versions of General Relativity (GR from now on). More specifically, it deals with a unified formalism [BLEEdD · 07, ELM · 04, Vit10] for Palatini version of GR, pursuing the work initiated in [GRR17] for Einstein-Hilbert action. Also, a novel unified version of unimodular gravity is obtained as a by-product of the geometrical tools employed in the article.…”

Section: Introductionmentioning

confidence: 99%

Unified formalism for Palatini gravity

Capriotti

2018

Int. J. Geom. Methods Mod. Phys.

View full text Add to dashboard Cite

The present article is devoted to the construction of a unified formalism for Palatini and unimodular gravity. The basic idea is to employ a relationship between unified formalism for a Griffiths variational problem and its classical Lepage-equivalent variational problem. As a way to understand from an intuitive viewpoint the Griffiths variational problem approach considered here, we may say the variations of the Palatini Lagrangian are performed in such a way that the so called metricity condition, i.e. (part of) the condition ensuring that the connection is the Levi-Civita connection for the metric specified by the vielbein, is preserved. From the same perspective, the classical Lepage-equivalent problem is a geometrical implementation of the Lagrange multipliers trick, so that the metricity condition is incorporated directly into the Palatini Lagrangian. The main geometrical tools involved in these constructions are canonical forms living on the first jet of the frame bundle for the spacetime manifold Å . These forms play an essential rôle in providing a global version of the Palatini Lagrangian and expressing the metricity condition in an invariant form; with their help, it was possible to formulate an unified formalism for Palatini gravity in a geometrical fashion. Moreover, we were also able to find the associated equations of motion in invariant terms and, by using previous results from the literature, to prove their involutivity. As a bonus, we showed how this construction can be used to provide a unified formalism for the so called unimodular gravity by employing a reduction of the structure group of the principal bundle ÄÅ to the special linear group ËÄ´Ñµ Ñ dim Å .

show abstract

Section: Introductionmentioning

confidence: 99%

Unified formalism for Palatini gravity

Capriotti

2018

Int. J. Geom. Methods Mod. Phys.

View full text Add to dashboard Cite

show abstract

“…Other recent discussions of gauge fields and gravity from the point of view of classical DW Hamiltonian theory and its geometrizations can be found in [30][31][32][33][34][35][36].…”

Section: Introductionmentioning

confidence: 99%

SchrÖdinger Wave Functional in Quantum Yang–Mills Theory from Precanonical Quantization

Kanatchikov

2018

Reports on Mathematical Physics

View full text Add to dashboard Cite

A relation between the precanonical quantization of pure Yang-Mills fields and the standard functional Schrödinger representation in the temporal gauge is discussed. It is shown that the latter can be obtained from the former when the ultraviolet parameter κ introduced in precanonical quantization goes to infinity. In this limiting case, the Schrödinger wave functional can be expressed as the trace of the Volterra product integral of Clifford-algebra-valued precanonical wave functions restricted to a field configuration, and the canonical functional derivative Schrödinger equation together with the quantum Gauß constraint can be derived from the Dirac-like precanonical Schrödinger equation.

show abstract

“…The multiplicity of the semiholonomic solutions of the Einstein-Hilbert model appears in the second derivative of the components of the metric (in the Hamiltonian formalism using the non-momentum coordinates). They are of the form (see [25])…”

Section: Relation Between the Einstein-hilbert And The Metric-affine mentioning

confidence: 99%

“…In recent years, there is an increasing effort in understanding the covariant description of gravitational theories (General Relativity and other derived from it) using different kinds of geometric frameworks such as the multisymplectic or the polysymplectic manifolds. Thus, in [3,8,9,10,21,25,26,27,35,36,43,44,46] general aspects of the theory are studied in this way, meanwhile other papers are devoted to consider several particular problems. For instance, in [7,24,41,42] the reduction and projectability of higher-order theories (such as the Hilbert-Einstein model) is analized, in [47] the vielbein models of General Relativity are studied using the multisymplectic formulation and in [32,33,34] interesting contributions to the problem of the precanonical quantization of gravity are done.…”

Section: Introductionmentioning

confidence: 99%

New multisymplectic approach to the Metric-Affine (Einstein-Palatini) action for gravity

Gaset

Román‐Roy

2019

Journal of Geometric Mechanics

Self Cite

View full text Add to dashboard Cite

We present a covariant multisymplectic formulation for the Einstein-Palatini (or Metric-Affine) model of General Relativity (without energy-matter sources). As it is described by a first-order affine Lagrangian (in the derivatives of the fields), it is singular and, hence, this is a gauge field theory with constraints. These constraints are obtained after applying a constraint algorithm to the field equations, both in the Lagrangian and the Hamiltonian formalisms. In order to do this, the covariant field equations must be written in a suitable geometrical way, using integrable distributions which are represented by multivector fields of a certain type. We obtain and explain the geometrical and physical meaning of the Lagrangian constraints and we construct the multimomentum (covariant) Hamiltonian formalism. The gauge symmetries of the model are discussed in both formalisms and, from them, the equivalence with the Einstein-Hilbert model is established.

show abstract

Multisymplectic unified formalism for Einstein-Hilbert gravity

Cited by 32 publications

References 45 publications

Unified formalism for Palatini gravity

Unified formalism for Palatini gravity

SchrÖdinger Wave Functional in Quantum Yang–Mills Theory from Precanonical Quantization

New multisymplectic approach to the Metric-Affine (Einstein-Palatini) action for gravity

Contact Info

Product

Resources

About