Kinematic state of an interacting cosmology modeled with Chebyshev polynomials

Abstract

In a spatially flat universe and for an interacting cosmology, we have reconstructed the interaction term, Q, between a cold dark matter (DM) fluid and a dark energy (DE) fluid, as well as a time-varying equation of state (EoS) parameter ωDE, and have explored their cosmological impacts on the amplitudes of the first six cosmographic parameters, which allow us to extract information about the kinematic state of the universe today. Here, both Q and ωDE have been modeled in terms of the Chebyshev polynomials. Then, via a Markov-Chain Monte Carlo (MCMC) method, we have constrained the model parameter space by using a combined analysis of geometric data. Our results show that the evolution curves of the cosmographic parameters deviate strongly from those predicted in the standard model when are compared, namely, they are much more sensitive to Q and ωDE during their cosmic evolution. In this context, we have also found that different DE scenarios could be compared and distinguished among them, by using the present values of the highest order cosmographic parameters.