Saved in:
Bibliographic Details
Main Authors: Liu, Jingwei, Melia, Fulvio
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2404.10956
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866916209990041600
author Liu, Jingwei
Melia, Fulvio
author_facet Liu, Jingwei
Melia, Fulvio
contents Space-based missions studying the cosmic microwave background (CMB) have progressively refined the parameter space in conventional models of inflation shortly ($\sim 10^{-37}$ seconds) after the big bang. While most inflationary scenarios proposed thus far in the context of GR have since been ruled out, the basic idea of inflation may still be tenable, albeit with several unresolved conundrums, such as conflicting initial conditions and inconsistencies with the measured CMB power spectrum. In the new slow-roll inflationary picture, inflation arising in plateau-like potentials requires an initiation beyond the Planck time. This delay may be consistent with the cutoff, $k_{\rm min}$, measured recently in the primordial power spectrum. However, the actual value of $k_{\rm min}$ would imply an initiation time too far beyond the big bang for inflation to solve the horizon problem. In this paper, we also describe several other undesirable consequences of this delay, including an absence of well motivated initial conditions and a significant difficulty providing a viable mechanism for properly quantizing the primordial fluctuations. Nevertheless, many of these inconsistencies may still be avoided if one introduces non-conventional modifications to inflation, such as a brief departure from slow-roll dynamics, possibly due to a dramatic change in the inflationary potential, inflation driven by multiple fields, or a non-minimal coupling to gravity. In addition, some of these difficulties could be mitigated via the use of alternative cosmologies based, e.g., on loop quantum gravity, which replaces the initial big-bang singularity with finite conditions at a bounce-like beginning.
format Preprint
id arxiv_https___arxiv_org_abs_2404_10956
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Challenges to Inflation in the Post-Planck Era
Liu, Jingwei
Melia, Fulvio
Cosmology and Nongalactic Astrophysics
Space-based missions studying the cosmic microwave background (CMB) have progressively refined the parameter space in conventional models of inflation shortly ($\sim 10^{-37}$ seconds) after the big bang. While most inflationary scenarios proposed thus far in the context of GR have since been ruled out, the basic idea of inflation may still be tenable, albeit with several unresolved conundrums, such as conflicting initial conditions and inconsistencies with the measured CMB power spectrum. In the new slow-roll inflationary picture, inflation arising in plateau-like potentials requires an initiation beyond the Planck time. This delay may be consistent with the cutoff, $k_{\rm min}$, measured recently in the primordial power spectrum. However, the actual value of $k_{\rm min}$ would imply an initiation time too far beyond the big bang for inflation to solve the horizon problem. In this paper, we also describe several other undesirable consequences of this delay, including an absence of well motivated initial conditions and a significant difficulty providing a viable mechanism for properly quantizing the primordial fluctuations. Nevertheless, many of these inconsistencies may still be avoided if one introduces non-conventional modifications to inflation, such as a brief departure from slow-roll dynamics, possibly due to a dramatic change in the inflationary potential, inflation driven by multiple fields, or a non-minimal coupling to gravity. In addition, some of these difficulties could be mitigated via the use of alternative cosmologies based, e.g., on loop quantum gravity, which replaces the initial big-bang singularity with finite conditions at a bounce-like beginning.
title Challenges to Inflation in the Post-Planck Era
topic Cosmology and Nongalactic Astrophysics
url https://arxiv.org/abs/2404.10956