Breaking Eternal Inflation: Empirical Viability of a Spontaneous Collapse Scenario

TL;DR

This paper investigates a quantum collapse-based inflation model that explains cosmic structures, suppresses eternal inflation, and aligns with Planck CMB data, offering a novel approach to early universe cosmology.

Contribution

It introduces a spontaneous collapse scenario with new parameters that address primordial inhomogeneities and avoid eternal inflation, supported by observational data.

Findings

Model predicts a low-$ll$ suppression in CMB spectrum.

Planck data constrain the collapse parameters effectively.

The scenario explains cosmic structure and prevents eternal inflation.

Abstract

We revisit an inflationary scenario in which primordial inhomogeneities arise from a quantum collapse, a stochastic mechanism described in the context of quantum collapse theories in its continuous version and within semiclassical gravity. The predictions of the model show a non-conventional scalar spectrum governed by two new parameters in the collapse rate, whose aim is twofold: on one side, to account for the primordial cosmic structure, and on the other to explain the suppression amplitude associated with long-wavelength modes, thereby eliminating the occurrence of eternal inflation. Furthermore, this model can contribute to accounting for the lack of power anomaly in the low $l$ angular power spectra of the Cosmic Microwave Background (CMB). Using the latest data from the Planck (2018) collaboration, we establish observational constraints on the model parameters, which produce a characteristic low-$\ell$ suppression in the cosmic microwave background spectrum. We conclude that the Planck data support the solution presented in the previous works, in other words, that the model allows us to solve simultaneously the emergence of the cosmic structure and, at the same time, avoid the eternal inflation scenario.