Quantum-Corrected φ4 Inflation in Light of ACT Observations

Abstract

Recent measurements from the Atacama Cosmology Telescope (ACT), combined with Planck and DESI data, suggest a scalar spectral index ns higher than the Planck 2018 baseline, thereby placing conventional attractor-type inflationary models such as Starobinsky R2 and Higgs inflation under increasing tension at the 2σ level. In this work, we examine quantum-corrected φ4 inflation with a non-minimal coupling to gravity. Introducing an anomalous scaling parameter γ to capture quantum corrections to the effective potential, we derive analytic expressions for the inflationary observables ns and r. Confronting these predictions with ACT, Planck, and BAO+lensing constraints, we demonstrate that modest values of γ can raise ns into the ACT-preferred range while maintaining a strongly suppressed tensor-to-scalar ratio. For instance, with N=60 and γ 0.006, the model predicts ns 0.974 and r 0.007, in excellent agreement with current bounds. We further investigate preheating dynamics, focusing on particle production via parametric resonance in quantum-corrected φ4 inflation with a non-minimal coupling to gravity. In this scenario, the inflaton φ couples to an additional scalar through an interaction g2φ22. In Minkowski spacetime, the resonance dynamics reduce to the Mathieu equation, and we find that broad resonance can be readily achieved, leading to efficient particle production.