Jacobi's action and the recovery of time in general relativity
- 15 November 1989
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review D
- Vol. 40 (10) , 3312-3318
- https://doi.org/10.1103/physrevd.40.3312
Abstract
We argue that the usual action principle of general relativity, applied to spacetimes with closed spatial geometries, should be regarded as analogous to Jacobi's form of the principle of stationary action, in which the energy rather than a physical time is fixed. Following the paradigm of quantization based on Jacobi's action for a nonrelativistic particle, we show that the Wheeler-DeWitt equation corresponds to a time-independent Schrödinger equation. The relationship between Jacobi's and Hamilton's action principles then allows us to derive a time-dependent Wheeler-DeWitt equation of the Schrödinger type. In this equation, the role of energy is played by the cosmological constant and that of physical time by the four-volume of spacetime.Keywords
This publication has 16 references indexed in Scilit:
- Time and the interpretation of canonical quantum gravityPhysical Review D, 1989
- Unimodular theory of canonical quantum gravityPhysical Review D, 1989
- The cosmological constant and general covariancePhysics Letters B, 1989
- Quantum kinematics of spacetime. II. A model quantum cosmology with real clocksPhysical Review D, 1988
- Operator ordering and the flatness of the universeNuclear Physics B, 1986
- Wave function of the inflationary universePhysical Review D, 1984
- Path integrals in parametrized theories: Newtonian systemsJournal of Mathematical Physics, 1984
- Measure for measure: Covariant skeletonizations of phase space path integrals for systems moving on Riemannian manifoldsJournal of Mathematical Physics, 1983
- The exchange of massless spin-two particlesPhysica A: Statistical Mechanics and its Applications, 1982
- Three-Dimensional Geometry as Carrier of Information about TimePhysical Review B, 1962