Non-gaussianities and the Stimulated creation of quanta in the inflationary universe

TL;DR

This paper investigates how initial non-vacuum states during inflation can lead to enhanced non-gaussianities in the primordial bispectrum, providing a potential observational window into the universe's initial conditions.

Contribution

It introduces a framework for analyzing stimulated creation of perturbations from a mixed initial state, revealing their impact on non-gaussianities in single-field inflation.

Findings

Initial perturbations can significantly enhance non-gaussianities in the squeezed limit.

Non-vacuum initial states can produce observable non-gaussian signals.

The primordial bispectrum is sensitive to the initial quantum state of inflation.

Abstract

Cosmological inflation generates a spectrum of density perturbations that can seed the cosmic structures we observe today. These perturbations are usually computed as the result of the gravitationally-induced spontaneous creation of perturbations from an initial vacuum state. In this paper, we compute the perturbations arising from gravitationally-induced stimulated creation when perturbations are already present in the initial state. The effect of these initial perturbations is not diluted by inflation and survives to its end, and beyond. We consider a generic statistical density operator $\rho$ describing an initial mixed state that includes probabilities for nonzero numbers of scalar perturbations to be present at early times during inflation. We analyze the primordial bispectrum for general configurations of the three different momentum vectors in its arguments. We find that the initial presence of quanta can significantly enhance non-gaussianities in the so-called squeezed limit. Our results show that an observation of non-gaussianities in the squeezed limit can occur for single-field inflation when the state in the very early inflationary universe is not the vacuum, but instead contains early-time perturbations. Valuable information about the initial state can then be obtained from observations of those non-gaussianities.