Exploring generalized Starobinsky Model of Inflation: Observational Constraints
Abstract
We examine the power-law Starobinsky model, a generalized version of the Starobinsky inflation model, characterized by a power-law correction to Einstein gravity. Employing the f(R) formalism, the scalar and tensor power spectra were numerically computed as functions of the dimensionless parameters M and β. A Markov Chain Monte Carlo (MCMC) analysis was conducted using Planck-2018, BICEP3 and BAO observational data, yielding precise constraints on β = 1.987+0.013-0.016,\, 95\%\, C.\, L.. and 10M = -4.72+0.21-0.20. The derived scalar spectral index ns=0.9676+0.0069-0.0068 and tensor-to-scalar ratio r=0.0074+0.0061-0.0044 lie within the bounds set by Planck observations. We analyse a general reheating scenario while keeping the number of e-folds during inflation, Npivot, fixed. The analysis confirms that deviations from the Starobinsky R2 model are observationaly viable, with implications for high-energy physics and supergravity-based inflationary models.
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