Sub-Planckian φ2 Inflation in the Palatini Formulation of Gravity with an R2 term

Abstract

In the context of the Palatini formalism of gravity with an R2 term, a φ2 potential can be consistent with the observed bound on r whilst retaining the successful prediction for ns. Here we show that the Palatini φ2 R2 inflation model can also solve the super-Planckian inflaton problem of φ2 chaotic inflation, and that the model can be consistent with Planck scale-suppressed potential corrections. If α 1012, where α is the coefficient of the R2 term, the inflaton in the Einstein frame, σ, remains sub-Planckian throughout inflation. In addition, if α 1020 then the predictions of the model are unaffected by Planck-suppressed potential corrections in the case where there is a broken shift symmetry, and if α 1032 then the predictions are unaffected by Planck-suppressed potential corrections in general. The value of r is generally small, with r 10-5 for α 1012. We calculate the maximum possible reheating temperature, TR\;max, corresponding to instantaneous reheating. For α ≈ 1032, TR\; max is approximately 1010 GeV, with larger values of TR\;max for smaller α. For the case of instantaneous reheating, we show that ns is in agreement with the 2018 Planck results to within 1-σ, with the exception of the α ≈ 1032 case, which is close to the 2-σ lower bound. Following inflation, the inflaton condensate is likely to rapidly fragment and form oscillons. Reheating via inflaton decays to right-handed neutrinos can easily result in instantaneous reheating. We determine the scale of unitarity violation and show that, in general, unitarity is conserved during inflation.