Unique Fock quantization of scalar cosmological perturbations

TL;DR

This paper establishes a unique Fock quantization scheme for scalar cosmological perturbations in a closed universe model, ensuring invariance under symmetries and unitary evolution, thus resolving quantization ambiguities.

Contribution

It demonstrates the uniqueness of the Fock quantization for scalar perturbations in a closed FLRW universe with a massive scalar field, based on symmetry and unitarity criteria.

Findings

Identifies a unique class of Fock representations invariant under spatial symmetries.

Shows the quantization can be achieved through mode-by-mode unitary transformations.

Provides a gauge-invariant quantization approach with a canonical structure.

Abstract

We investigate the ambiguities in the Fock quantization of the scalar perturbations of a Friedmann-Lema\^{i}tre-Robertson-Walker model with a massive scalar field as matter content. We consider the case of compact spatial sections (thus avoiding infrared divergences), with the topology of a three-sphere. After expanding the perturbations in series of eigenfunctions of the Laplace-Beltrami operator, the Hamiltonian of the system is written up to quadratic order in them. We fix the gauge of the local degrees of freedom in two different ways, reaching in both cases the same qualitative results. A canonical transformation, which includes the scaling of the matter field perturbations by the scale factor of the geometry, is performed in order to arrive at a convenient formulation of the system. We then study the quantization of these perturbations in the classical background determined by the homogeneous variables. Based on previous work, we introduce a Fock representation for the perturbations in which: (a) the complex structure is invariant under the isometries of the spatial sections and (b) the field dynamics is implemented as a unitary operator. These two properties select not only a unique unitary equivalence class of representations, but also a preferred field description, picking up a canonical pair of field variables among all those that can be obtained by means of a time-dependent scaling of the matter field (completed into a linear canonical transformation). Finally, we present an equivalent quantization constructed in terms of gauge-invariant quantities. We prove that this quantization can be attained by a mode-by-mode time-dependent linear canonical transformation which admits a unitary implementation, so that it is also uniquely determined.