T2- inflation: Sourced by energy-momentum squared gravity

Abstract

In this paper, we examine chaotic inflation within the context of the energy-momentum squared gravity (EMSG) focusing on the energy-momentum powered gravity (EMPG) that incorporates the functional f(T2) (T2)β in the Einstein-Hilbert action, in which β is a constant and T2 Tμ Tμ where Tμ is the energy-momentum tensor, which we consider to represent a single scalar field with a power-law potential. We demonstrate that the presence of EMSG terms allows the single-field monomial chaotic inflationary models to fall within current observational constraints, which are otherwise disfavored by Planck and BICEP/Keck findings. We show that the use of a non-canonical Lagrangian with chaotic potential in EMSG can lead to significantly larger values of the non-Gaussianity parameter, f Nl equi whereas EMSG framework with canonical Lagrangian gives rise to results similar to those of the standard single-field model.