Precision predictions of Starobinsky inflation with self-consistent Weyl-squared corrections

Abstract

Starobinsky's R+α R2 inflation provides a compelling one-parameter inflationary model that is supported by current cosmological observations. However, at the same order in spacetime derivatives as the R2 term, an effective theory of spacetime geometry must also include the Weyl-squared curvature invariant W2. In this paper, we study the inflationary predictions of the gravitational theory with action of the form R+α R2 - β W2, where the coupling constant α sets the scale of inflation, and corrections due to the W2 term are treated self-consistently via reduction of order in an expansion in the coupling constant β, at the linear order in β/α. Cosmological perturbations are found to be described by an effective action with a nontrivial speed of sound cs for scalar and ct for tensor modes, satisfying the relation ct/cs 1+ β6\, α during the inflationary phase. Within this self-consistent framework, we compute several primordial observables up to the next-to-next-to-next-to leading order (N3LO). We find the tensor-to-scalar ratio r 3(1-β6α)(ns-1)2, the tensor tilt nt-r8 and the running of the scalar tilt as-12 (ns - 1)2, all expressed in terms of the observed scalar tilt ns. We also provide the corresponding corrections up to N3LO, O((ns - 1)3).