A complete analysis of inflation with piecewise quadratic potential
Abstract
We conduct a thorough study of the comoving curvature perturbation R in single-field inflation with two stages, represented by a piecewise quadratic potential, where both the first and second derivatives are allowed to be discontinuous at the transition point. We calculate the evolution of R by combining the perturbative and non-perturbative methods consistently, and obtain the power spectrum and the non-Gaussian features in the probability distribution function. We find that both the spectrum and the statistics of R depend significantly on the second derivatives of the potential at both the first and second stages. Furthermore, we find a new parameter constructed from the potential parameters, which we call α, plays a decisive role in determining various features in the spectrum such as the amplitude, the slope, and the existence of a dip. In particular, we recover the typical k4 growth of the spectrum in most cases, but the maximum growth rate of k5( k)2 can be obtained by fine-tuning the parameters. Then, using the δ N formalism valid on superhorizon scales, we give fully nonlinear formulas for R in terms of the scalar field perturbation δφ and its time derivative. In passing, we point out the importance of the nonlinear evolution of δφ on superhorizon scales. Finally, using the Press-Schechter formalism for simplicity, we discuss the effect of the non-Gaussian tails of the probability distribution function on the primordial black hole formation.
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