Inflation in an effective gravitational model & asymptotic safety

Abstract

We consider an inflationary model motivated by quantum effects of gravitational and matter fields near the Planck scale. Our Lagrangian is a re-summed version of the effective Lagrangian recently obtained by Demmel, Saueressig and Zanusso~Demmel:2015oqa in the context of gravity as an asymptotically safe theory. It represents a refined Starobinsky model, L eff=M P2 R/2 + (a/2)R2/[1+b(R/μ2)], where R is the Ricci scalar, a and b are constants and μ is an energy scale. By implementing the COBE normalisation and the Planck constraint on the scalar spectrum, we show that increasing b leads to an increased value of both the scalar spectral index ns and the tensor-to-scalar ratio r. Requiring ns to be consistent with the Planck collaboration upper limit, we find that r can be as large as r 0.01, the value possibly measurable by Stage IV CMB ground experiments and certainly from future dedicated space missions. The predicted running of the scalar spectral index α=d ns/d(k) is still of the order -5× 10-4 (as in the Starobinsky model), about one order of magnitude smaller than the current observational bound.