Higgs-like inflation under ACTivated mass

Abstract

Recent analyses that combine the latest data from the Atacama Cosmology Telescope (ACT) with cosmic microwave background observations by BICEP/Keck and Planck, together with the DESI baryon acoustic-baryonic-oscillation (BAO) measurements, have tightened the limits on inflationary scenarios. The joint data set yields a spectral index of primordial scalar perturbations ns = 0.9743 0.0034 and an upper bound on the tensor-to-scalar ratio of r < 0.038. This slight upward shift in ns puts the previously favored Starobinsky model, and the conventional metric Higgs(-like) inflation--based on a quartic potential with a large non-minimal coupling in the Jordan frame--under tension with observations. In metric Higgs-like inflation the attractor behavior makes the predictions remarkably stable against higher-order operators, so modifying ns through such terms is difficult. In this paper, I show that adding a quadratic mass term to the Jordan-frame potential can raise ns and restore compatibility with the new data. I also discuss how this mass term can naturally arise from threshold effects in Higgs inflation.