Scalar perturbation spectra from warm inflation

A. Albrecht; A. Berera; A. Berera; A. Berera; A. Berera; A. Berera; A. Berera; A. Berera; A. Berera; A. Berera; A. Hosoya; A. Linde; A.D. Linde; A.D. Linde; A.H. Guth; A.N. Taylor; A.R. Liddle; A.R. Liddle; Arjun Berera; C.L. Bennett; D.H. Lyth; E. Calzeta; E. Calzeta; E.D. Stewart; E.J. Copeland; G.J.S. Habib; H. Kodama; H.P. de Oliveira; H.P. de Oliveira; H.P. de Oliveira; H.V. Peiris; I.D. Lawrie; I.G. Moss; I.G. Moss; Ian G. Moss; J. chan Hwang; J. Martin; J. Schwinger; J. Yokoyama; J. Yokoyama; J.M. Bardeen; J.M.F. Maia; L. Dolan; L.P. Chimento; L.V. Keldysh; Lisa M. H. Hall; M. Bellini; M. Gleiser; P.P.A.R. Liddle; S.M. Leach; S.R. Lonsdale; S.W. Hawking; V.N. Lukash; W. Lee

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Scalar perturbation spectra from warm inflation

Abstract

We present a numerical integration of the cosmological scalar perturbation equations in warm inflation. The initial conditions are provided by a discussion of the thermal fluctuations of an inflaton field and thermal radiation using a combination of thermal field theory and thermodynamics. The perturbation equations include the effects of a damping coefficient

\Gamma

and a thermodynamic potential

V

. We give an analytic expression for the spectral index of scalar fluctuations in terms of a new slow-roll parameter constructed from

\Gamma

. A series of toy models, inspired by spontaneous symmetry breaking and a known form of the damping coefficient, lead to a spectrum with

n_s>1

on large scales and

n_s<1

on small scales.Comment: 12 pages, 5 figures, RevTeX 4, revised with extra figure

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Last time updated on 02/01/2020