Inflationary Decoherence from the Gravitational Floor

Abstract

We re-examine the decoherence rate of primordial fluctuations within minimal inflationary models, using only the gravitational interactions required for the underlying fluctuation-generation mechanism itself. Since gravity provides the weakest interactions the result provides a plausible floor on the rate of primordial decoherence. Previous calculations (arXiv:2211.11046) did so using only a subset of these interactions, motivated by assuming both system and environment were super-Hubble. We extend this by including the effects on super-Hubble modes of all gravitational interactions at leading order in H/Mp (and so need not restrict the decohering environment to being super-Hubble). We show how the decohering evolution becomes Markovian for super-Hubble modes, without the need to appeal to truncations (like the `rotating wave' approximation) that are often used in optics but can be inapprorpriate for cosmology. We find that the dominant contribution comes from the nonlocal cubic interactions obtained by solving the constraints. We identify UV divergences systematically and verify thereby that the leading part of the purity evolution is UV finite. In the end we find a decoherence rate that grows in the super-Hubble regime significantly faster than found earlier. We take the preliminary steps to resum this result to late times and briefly discuss why they are more complicated than for earlier calculations.