Globally stable, ghost-free hyperbolic square-root deformation of the Starobinsky model

Abstract

We propose an exact, analytic deformation of the Starobinsky model governed by the strictly positive derivative of its Lagrangian, f'(R) = α R + α2 R2 + 1, with α > 0. This geometric hyperbolic square-root ansatz is designed to eliminate the well-known strong-coupling singularity that arises in quadratic f(R) gravity when f'(R)=0. The construction seamlessly recovers general relativity at low curvatures and preserves the successful slow-roll inflationary plateau at extreme positive curvatures. In the limit R -∞, the derivative f'(R) asymptotes to zero strictly from above, removing the pathological branch associated with the vanishing of f'(R). This guarantees that the only admissible constant-curvature (R=A) solutions correspond to standard Einstein spaces with an effective cosmological constant eff A/4. The first and second derivatives of the action, as well as the scalaron mass squared, remain strictly positive globally, ensuring a perfectly ghost-free and tachyon-free cosmological evolution across the entire spacetime manifold. In the Einstein frame, the dynamics of the scalaron is governed by the globally defined potential V(φ) = 18α [ 1 - (1 + 22/3φ) (-22/3φ) ] + (-22/3φ), which naturally establishes an impenetrable energetic wall as φ -∞, offering a robust, globally stable mechanism for non-singular bouncing cosmologies. For N = 60 inflationary e-folds, the model predicts a scalar spectral index of ns 0.967 and a strongly suppressed tensor-to-scalar ratio of r 0.00083, which position the proposed theory within the observationally favored parameter space of the Planck and BICEP/Keck Array baseline constraints.

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