Kinetic Initial Conditions for Inflation
Abstract
We consider the classical evolution of the inflaton field and the Hubble parameter in homogeneous and isotropic single-field inflation models. Under an extremely broad assumption, we show that the universe generically emerges from an initial singularity in a non-inflating state where the kinetic energy of the inflaton dominates its potential energy, . In this kinetically-dominated regime, the dynamical equations admit simple analytic solutions for and , which are independent of the form of . In such models, these analytic solutions thus provide a simple way of setting the initial conditions from which to start the (usually numerical) integration of the coupled equations of motion for and . We illustrate this procedure by applying it to spatially-flat models with polynomial and exponential potentials, and determine the background evolution in each case; generically and as well as their time derivatives decrease during kinetic dominance until , marking the onset of a brief period of fast-roll inflation prior to a slow roll phase. We also calculate the approximate spectrum of scalar perturbations produced in each model and show that it exhibits a generic damping of power on large scales. This may be relevant to the apparent low- falloff in the CMB power spectrum.
Cite
@article{arxiv.1401.2253,
title = {Kinetic Initial Conditions for Inflation},
author = {W. J. Handley and S. D. Brechet and A. N. Lasenby and M. P. Hobson},
journal= {arXiv preprint arXiv:1401.2253},
year = {2018}
}
Comments
Accepted by Physical Review D, 20 pages, 14 figures. v3 contains a significant correction to the proof, submitted as an errata to PRD