Minimal Extensions of the α-Starobinsky Model: Reconciling ACT DR6 and Reheating Constraints

Abstract

The latest combined data from the Atacama Cosmology Telescope (ACT) DR6, Planck, and DESI yields a scalar spectral index ns = 0.9743 0.0034, which lies approximately 2σ above the prediction of the standard α-Starobinsky inflation model. To address this tension, we propose two minimal extensions that preserve the model's plateau structure and attractor properties: a multiplicative exponential modification and an additive polynomial deformation, both governed by a single small perturbative parameter δ>0. We analytically derive the slow-roll parameters and inflationary observables up to second order in δ and integrate them with reheating dynamics via the consistency equation. It is shown that the δ term effectively shifts ns into the 1σ confidence region of the joint P-ACT-LB-BK18 dataset without violating the tensor-to-scalar ratio bound (r < 0.038). The viable parameter space at 1σ requires α 35 with δ O(10-2) for the exponential model, while the additive model requires δ O(10-3) for p=1 and δ O(10-4) for p=2. For the e-folding range Nk ∈ [50, 65], the relevant reheating equation of state is 0<ωre1. All viable scenarios yield a reheating temperature Tre 109 GeV, which is safely above the Big Bang Nucleosynthesis (BBN) bound and below the gravitino overproduction limit.