A minisuperspace model of compact phase space gravity
Résumé
The kinematical phase space of classical gravitational field is flat (affine) and unbounded. Because of this, field variables may tend to infinity, leading to appearance of singularities, which plague Einstein’s theory of gravity. The purpose of this article is to study the idea of generalizing the theory of gravity by compactification of the phase space. We investigate the procedure of compactification of the phase space on a minisuperspace gravitational model with two-dimensional phase space. In the affine limit, the model reduces to the flat de Sitter cosmology. The phase space is generalized to the spherical case, and the case of loop quantum cosmology is recovered in the cylindrical phase space limit. Analysis of the dynamics reveals that the compactness of the phase space leads to both UV and IR effects. In particular, the phase of recollapse appears, preventing the Universe from expanding to infinite volume. Furthermore, the quantum version of the model is investigated and the quantum constraint is solved. As an example, we analyze the case with the spin quantum number s=2, for which we determine transition amplitude between initial and final state of the classical trajectory. The probability of the transition is peaked at Λ=0.
Mots clés
Cosmology
kinematics: phase space
gravitation: model
gravitation: classical
trajectory: classical
constraint: quantum
dimension: 2
quantum cosmology: loop space
compactification
minisuperspace
cosmological model
quantum number
singularity
space-time: de Sitter
space-time: Robertson-Walker
Friedman model
general relativity
gravitation
spin