Inflation in the Scale Symmetric Standard Model and Weyl geometry

Abstract

This work explores the possibility of inflation in a scale-symmetric extension of the Standard Model Higgs sector, where the Higgs field φ1 is coupled to a singlet scalar, the dilaton φ0. The two-scalar theory is formulated within Weyl geometry, which modifies the Einstein frame form of the resulting single-field inflationary potential. We extend the analysis to include quantum corrections, incorporating curvature effects in the one-loop effective potential. We find that the resulting spectral index ns and tensor-to-scalar ratio r0.002 can be consistent with the Planck 2018 observational constraints. The predicted value r0.002 10-6 remains too small to yield a detectable gravitational wave signal. In the regime with a strong hierarchy between the non-minimal couplings, 10, the unitarity cutoff in the large-field background, UV MP/1, lies below the energy scales relevant during inflation.