Late-time cosmology in a model of modified gravity with an exponential function of the curvature

Abstract

In this work, we analyse the late-time evolution of the universe for a particular f(R) gravity model built from an exponential function of the scalar curvature. Following the literature, we write the field equations in terms of a suited statefinder function (yH(z)) and considering well motivated physical initial conditions, the resulting equations are solved numerically. Also, the cosmological parameters wDE, weff, DE and H(z) and the statefinder quantities q, j, s and Om(z) are explicitly expressed in terms of yH(z) and its derivatives. Furthermore, setting an appropriate set of values for the model parameters, the cosmological parameters as well as the statefinder quantities are plotted, and their present values (at z=0), are shown to be compatible with Planck 2018 observations and the -model values. Considering updated measurements from the dynamics of the expansion of the universe, H(z), we perform an statistical analysis to constrain the free parameters of the model, finding a particular set of values that fit the data well and predict acceptable values for the cosmological and statefinder parameters at present time. Therefore, the f(R) gravity model is found to be consistent with the considered observational data, and a viable alternative to explain the late-time acceleration of the universe.