Email this article Von Neumann’s quantization of general relativity
- Authors: Arbuzov A.B.1,2, Cherny A.Y.1, Cirilo-Lombardo D.J.1,3, Nazmitdinov R.G.1,4, Han N.S.5, Pavlov A.E.1,6, Pervushin V.N.1, Zakharov A.F.1,7
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Affiliations:
- Joint Institute for Nuclear Research
- University Dubna
- National Institute for Plasma Physics (INFIP-CONICET), FCEyN
- Universitat de les Illes Balears
- Hanoi University of Science
- Russian State Agrarian University
- Institute for Theoretical and Experimental Physics
- Issue: Vol 80, No 3 (2017)
- Pages: 491-504
- Section: Elementary Particles and Fields Theory
- URL: https://journals.rcsi.science/1063-7788/article/view/191885
- DOI: https://doi.org/10.1134/S106377881702003X
- ID: 191885
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Abstract
Von Neumann’s procedure is applied to quantizing general relativity. Initial data for dynamical variables in the Planck epoch, where the Hubble parameter value coincided with the Planck mass are quantized. These initial data are defined in terms of the Fock orthogonal simplex in the tangent Minkowski spacetime and the Dirac conformal interval. The Einstein cosmological principle is used to average the logarithm of the determinant of the spatial metric over the spatial volume of the visible Universe. The splitting of general coordinate transformations into diffeomorphisms and transformations of the initial data is introduced. In accordance with von Neumann’s procedure, the vacuum state is treated is a quantum ensemble that is degenerate in quantum numbers of nonvacuum states. The distribution of the vacuum state leads to the Casimir effect in gravidynamics in just the same way as in electrodynamics. The generating functional for perturbation theory in gravidynamics is found by solving the quantum energy constraint. The applicability range of gravidynamics is discussed along with the possibility of employing this theory to interpret modern observational data.
About the authors
A. B. Arbuzov
Joint Institute for Nuclear Research; University Dubna
Author for correspondence.
Email: arbuzov@theor.jinr.ru
Russian Federation, ul. Joliot-Curie 6, Dubna, Moscow oblast, 141980; Universitetskaya ul. 19, Dubna, Moscow oblast, 141982
A. Yu. Cherny
Joint Institute for Nuclear Research
Email: arbuzov@theor.jinr.ru
Russian Federation, ul. Joliot-Curie 6, Dubna, Moscow oblast, 141980
D. J. Cirilo-Lombardo
Joint Institute for Nuclear Research; National Institute for Plasma Physics (INFIP-CONICET), FCEyN
Email: arbuzov@theor.jinr.ru
Russian Federation, ul. Joliot-Curie 6, Dubna, Moscow oblast, 141980; Buenos Aires, 1428
R. G. Nazmitdinov
Joint Institute for Nuclear Research; Universitat de les Illes Balears
Email: arbuzov@theor.jinr.ru
Russian Federation, ul. Joliot-Curie 6, Dubna, Moscow oblast, 141980; Cra. de Valldemossa, km 7.5, Palma (Illes Balears), 07122
Nguyen Suan Han
Hanoi University of Science
Email: arbuzov@theor.jinr.ru
Viet Nam, Hanoi
A. E. Pavlov
Joint Institute for Nuclear Research; Russian State Agrarian University
Email: arbuzov@theor.jinr.ru
Russian Federation, ul. Joliot-Curie 6, Dubna, Moscow oblast, 141980; Timiryazevskaya ul. 49, Moscow, 127550
V. N. Pervushin
Joint Institute for Nuclear Research
Email: arbuzov@theor.jinr.ru
Russian Federation, ul. Joliot-Curie 6, Dubna, Moscow oblast, 141980
A. F. Zakharov
Joint Institute for Nuclear Research; Institute for Theoretical and Experimental Physics
Email: arbuzov@theor.jinr.ru
Russian Federation, ul. Joliot-Curie 6, Dubna, Moscow oblast, 141980; Bol’shaya Cheremuskinskaya ul. 25, Moscow, 117218
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