Constrained transit cosmological models in f(R,Lm,T)-gravity

Abstract

In the present paper, we investigate constrained transit cosmological models in the most recent proposed modified gravity theory, f(R,Lm,T)-gravity. We obtain the modified field equations for a flat homogeneous and isotropic Friedmann-Lema\tre-Robertson-Walker (FLRW) spacetime metric. We constrain the equation of continuity by imposing the equation of state for the perfect fluid source p=-13+p0 so that we get energy conservation equation as +3H(+p)=0, (because generally, energy conservation law is not satisfied in f(R,Lm,T)-gravity). Using this constraint, we establish a relation between the energy density parameters m0, r0, and f0 and the Hubble function. After that, we made observational constraints on H(z) to obtain the best-fit present values of m0, r0, and H0. Then, we use these best-fit values of energy parameters to investigate cosmological parameters such as the deceleration parameter, the effective equation of state ωeff, and the energy density parameters m, r, and f to learn more about the components and history of the expanding universe. We found an effective EoS parameter in the range -1 ωeff13 with a deceleration-acceleration transition redshift value of zt=0.6377, 0.6424 along two datasets cosmic chronometer (CC) and Pantheon SNIa, respectively.