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February 6, 2026Open Access

Inflation in the scale symmetric Standard Model and Weyl geometry

Key Points

This research investigates inflation in a scale-symmetric extension of the Standard Model coupled with a dilaton.
Developed a two-scalar theory incorporating the Higgs and dilaton within Weyl geometry.
Analyzed the single-field inflationary potential in the modified Einstein frame.
Included quantum corrections with curvature effects in the effective potential.
Successfully aligned the spectral index n_s with observational constraints.
Predicted tensor-to-scalar ratio r 0.002 consistent with gravitational wave signals.
Determined unitarity cutoff as Λ UV ∼ M_P/√ξ_1 below inflation energy scales.

Abstract

A bstract This work explores the possibility of inflation in a scale-symmetric extension of the Standard Model Higgs sector, where the Higgs field ϕ 1 is coupled to a singlet scalar, the dilaton ϕ 0. 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 n s and tensor-to-scalar ratio r 0. 002 can be consistent with the observational constraints. The predicted value r 0. 002 ≲ 10 −3 is sufficient to yield a detectable gravitational wave signal. We find the unitarity cutoff in the large-field background, Λ UV ∼ MP/₁ M P / ξ 1, which lies below the energy scales relevant during inflation.

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Lalak et al. (Tue,) studied this question.

synapsesocial.com/papers/698585ea8f7c464f23009aa4 https://doi.org/https://doi.org/10.1007/jhep02(2026)041

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