Predictions from an anisotropic inflationary era

TL;DR

This paper explores how an initial anisotropic Bianchi I universe influences inflationary predictions, revealing directional dependencies in power spectra and the importance of initial conditions, especially in shear-dominated regimes.

Contribution

It introduces a method to set initial conditions in anisotropic inflation and analyzes how anisotropy affects observable spectra, highlighting the limits of predictability.

Findings

Spectra depend on mode direction and differ between gravity wave polarizations.

Anisotropic effects are significant on large scales and diminish on small scales.

Predictability is compromised for modes that violate the WKB condition during shear dominance.

Abstract

This article investigates the predictions of an inflationary phase starting from a homogeneous and anisotropic universe of the Bianchi I type. After discussing the evolution of the background spacetime, focusing on the number of e-folds and the isotropization, we solve the perturbation equations and predict the power spectra of the curvature perturbations and gravity waves at the end of inflation. The main features of the early anisotropic phase is (1) a dependence of the spectra on the direction of the modes, (2) a coupling between curvature perturbations and gravity waves, and (3) the fact that the two gravity waves polarisations do not share the same spectrum on large scales. All these effects are significant only on large scales and die out on small scales where isotropy is recovered. They depend on a characteristic scale that can, but a priori must not, be tuned to some observable scale. To fix the initial conditions, we propose a procedure that generalises the one standardly used in inflation but that takes into account the fact that the WKB regime is violated at early times when the shear dominates. We stress that there exist modes that do not satisfy the WKB condition during the shear-dominated regime and for which the amplitude at the end of inflation depends on unknown initial conditions. On such scales, inflation loses its predictability. This study paves the way to the determination of the cosmological signature of a primordial shear, whatever the Bianchi I spacetime. It thus stresses the importance of the WKB regime to draw inflationary predictions and demonstrates that when the number of e-folds is large enough, the predictions converge toward those of inflation in a Friedmann-Lemaitre spacetime but that they are less robust in the case of an inflationary era with a small number of e-folds.