Inflationary models in a minimally coupled f(R,T) gravity: Constraints from Planck, BICEP/Keck, and ACT

Abstract

The advent of high-precision cosmological observations has challenged many traditional inflationary models. Data from Planck 2018 along with the BICEP/Keck 2018 result have already ruled out most of the established models by placing tight constraints on the tensor-to-scalar ratio r. Upcoming missions like LiteBIRD & CMB-S4 are expected to impose an even more stringent bound on r, potentially excluding further models from the viable landscape. In this evolving observational context, modified gravity theories offer a promising way to reconcile inflationary models with data. In this work, we explore several inflationary models, namely mutated hilltop inflation, D-brane inflation, and Woods-Saxon inflation, within the framework of f(R,T) gravity. A minimally coupled and linear combination of Ricci scalar and trace of EM tensor is considered as f(R,T)=R+16πG λT and the cosmological observable parameters, viz. scalar spectral tilt ns, tensor-to-scalar ratio r, and running of scalar spectral index nsk are estimated for the three models, and their trajectories are plotted in the ns-r plane. The model results are evaluated in light of the Planck, BICEP/Keck, DESI DR2, and ACT DR6 data. We observe that for a certain model parameter space, these potentials are viable within the current observational bounds.