Bayesian Constraints on Inverse-Tangent Inflation with Constant-EOS Reheating and a Dynamical Reheating Analysis

Abstract

We perform a Bayesian inference analysis of an inflationary model based on an inverse-tangent potential, incorporating reheating dynamics in both constant and dynamical equation-of-state (DEOS) frameworks. Using Planck and ACT constraints on the scalar spectral index, we find preferred values κ0.5-0.6 and Nk40-60, leading to reheating temperatures TRH1010-1014 GeV and reheating durations NRH3-36 e-folds. Reheating weighted H0 posteriors shift the Planck inference towards the ACT preferred region through the intrinsic ns-H0 degeneracy of the CMB likelihood. In the DEOS framework, reheating with a constant decay rate yields NRH4-8 e-folds and TRH1013 GeV, while a dynamical decay rate produces a strong dependence on the Yukawa coupling y, with NRH varying from O(30) to O(1) e-folds and the reheating temperature spanning 10-2-1014 GeV. Imposing inflation-reheating consistency significantly restricts the viable parameter space to a narrow region around ns0.9720-0.9725 and r0.026-0.060, demonstrating that reheating dynamics provide a nontrivial bridge between early-universe inflation and late-time cosmological parameter inference.