Logarithmically enhanced hyperbolic square-root deformation of Starobinsky inflation
Abstract
We propose an enhanced hyperbolic square-root (HSQRT) deformation of the Starobinsky model in the context of f(R) gravity. The original HSQRT construction provided a globally regular modification of R2 inflation, curing the strong-coupling singularity at negative curvatures while preserving the exponential slow-roll plateau at large positive curvatures. Motivated by recent cosmological data (ACT DR6 and DESI), we introduce a structurally minimal, rational-logarithmic enhancement. This enhancement modifies the deep UV asymptotic regime while preserving global tachyon-free stability, ghost freedom, and the recovery of general relativity at low curvatures. In the Einstein frame, the scalaron dynamics is described by a globally defined, Pad\'e-regulated effective potential, VPad\'e(φ) = VStaro(φ) (1+ 4β 232φ2 + 1)-1 + 14α2 [1 - ( 1 + 23φ) e-23φ ] e-23φ, which exhibits the inverse-power asymptotic form at high curvatures, V(φ) 18α2 ( 1 - 6β2φ2 ), with the strength of the deviation from the baseline HSQRT geometry governed by dimensionless parameter β. We derive analytic expansions for the slow-roll observables, yielding a leading-order spectral index ns 1 - 3/(2N) and a tensor-to-scalar ratio r 23β/N3/2. For standard e-fold durations (N ∈ [50, 60]), this model drives the spectral index directly into the newly favored observational window (ns 0.970--0.975) and predicts an exceptionally small spectral running αs -3/(2N2) ∈ [-0.00060, -0.00042], establishing a viable target for next-generation CMB observatories.
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