Conventional and Unitarity-Conserving Peccei-Quinn Inflation Models and ACT
Abstract
We compare conventional non-minimally coupled Peccei-Quinn (PQ) inflation with a version of the model in which unitarity conservation is imposed by additional Jordan frame interactions. Assuming instantaneous reheating, the unitarity-conserving model is within 1σ agreement with the central value of the scalar spectral index reported by the ACT collaboration, whereas conventional PQ inflation is more than 2σ below the ACT central value. In the case where dark matter is composed of axions and PQ symmetry is not restored after inflation, the axion isocurvature constraint of the unitarity-conserving model typically allows a much larger axion decay constant fa than the conventional model, with the conventional model upper bound being comparable only if the PQ scalar self-coupling is extremely small, λ 10-10. For λ = 0.1, the axion isocurvature upper bounds are fa 1.1 × 109 GeV for conventional PQ inflation and fa 6.4 × 1013 GeV for unitarity-conserving PQ inflation, with the latter bound being independent of λ. We also find a new isocurvature upper bound for conventional PQ inflation which is 650 times smaller than the existing bound. A modest reduction of the reheating temperature of the unitarity-conserving model from its maximum possible value will ensure that the PQ symmetry is not restored after inflation, allowing values of fa up to 6.4 × 1013 GeV. Thus only the unitarity-conserving PQ inflation model allows fa to access values greater than the symmetry restoration cosmological upper bound 1012 GeV with naturally large values of the PQ scalar self-coupling.
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