Dilaton-Flattened Axion Inflation

Abstract

We present a solvable same-sector effective theory for anomaly-inspired axion inflation, in which a heavy trace-anomaly mode dynamically backreacts on the axion potential. The tree-level elimination of the radial field resums the backreaction into a closed-form Lambert-W potential, naturally flattening the hilltop potential without external plateau operators. By deriving the exact trough metric, we evaluate all the observables on the fully reduced one-field action, bypassing uncontrolled kinetic approximations. Calibrated at N=56, reheating-compatible branches yield r0.033--0.036 and αs-(4.6--4.7)×10-4, comfortably satisfying the current ACT/SPT/BICEP constraints. The evolution remains strictly adiabatic (m2/H26.1, /H7.6×10-4) with negligible sound-speed and metric corrections. We provide analytic control over the constant-w eff reheating map, the N re=0 boundary, and robustness against vacuum-offset deformations. This Lambert-W backbone establishes a precise, deformable benchmark for confining axion inflation, with microscopic matching and reheating microphysics accessible as systematic EFT refinements.