The Physical Relevance of the Fiducial Cell in Loop Quantum Cosmology

Abstract

A common way to avoid divergent integrals in homogeneous spatially non-compact gravitational systems is to introduce a fiducial cell by cutting-off the spatial slice at a finite region Vo. This is usually considered as an auxiliary regulator to be removed after computations by sending Vo∞. In this paper, we analyse the dependence of the classical and quantum theory of homogeneous, isotropic and spatially flat cosmology on Vo. We show that each fixed Vo regularisation leads to a different canonically independent theory. At the classical level, the dynamics of observables is not affected by the regularisation on-shell. For the quantum theory, however, this leads to a family of regulator dependent quantum representations and the limit Vo∞ becomes then more subtle. First, we construct a novel isomorphism between different Vo-regularisations, which allows us to identify states in the different Vo-labelled Hilbert spaces to ensure equivalent dynamics for any value of Vo. The Vo∞ limit would then correspond to choosing a state for which the volume assigned to the fiducial cell becomes infinite as appropriate in the late-time regime. As second main result of our analysis, quantum fluctuations of observables smeared over subregions V⊂ Vo, unlike those smeared over the full Vo, explicitly depend on the size of the fiducial cell through the ratio V/Vo interpreted as the (inverse) number of subcells V homogeneously patched together into Vo. Physically relevant fluctuations for a finite region, as e.g. in the early-time regime, which would be unreasonably suppressed in a na\"ive Vo∞ limit, become appreciable at small volumes. Our results suggest that the fiducial cell is not playing the role of a mere regularisation but is physically relevant at the quantum level and complement previous statements in the literature.