The formulation of General Relativity in extended phase space as a way to its quantization

TL;DR

This paper proposes a Hamiltonian formulation of General Relativity in extended phase space, offering a consistent approach to quantization that includes gauge degrees of freedom, addressing ambiguities in traditional formulations.

Contribution

It introduces an extended phase space formalism for General Relativity that is equivalent to the original Lagrangian formulation and suitable for quantization.

Findings

Extended phase space formulation is equivalent to the original Lagrangian theory.

Quantization in extended phase space is straightforward.

New quantum description emphasizes gauge degrees of freedom.

Abstract

Our attempts to find an explanation for quantum behavior of the Early Universe appeal, as a rule, to the Wheeler - DeWitt Quantum Geometrodynamics which relies upon Hamiltonian formulation of General Relativity proposed by Arnowitt, Deser and Misner (ADM). In spite of the fact that the basic ideas of this approach were put forward about fifty years ago, even now we do not have clear understanding what Hamiltonian formulation of General Relativity must be. An evidence for it gives a recent paper by Kiriushcheva and Kuzmin [arXiv:0809.0097], where the authors claim that the formulation by ADM and that by Dirac made in his seminal work of 1958 are not equivalent. If so, we face the question what formalism should be chosen. Another problem is that we need a well-grounded procedure of constructing a generator of transformations in phase space for all gravitational variables including gauge ones. It suggests the notion of extended phase space. After analyzing the situation, we show that Hamiltonian formulation in extended phase space is a real alternative to Dirac and ADM formulations and can be constructed to be equivalent to the original (Lagrangian) formulation of General Relativity. Quantization in extended phase space is straightforward and leads to a new description of quantum Universe in which an essential place is given to gauge degrees of freedom.