Comparative Study of Early-Universe Epochs in an f(R,Lm) Gravity Model with Effective Curvature--Matter Interaction and Cosmology

Abstract

We investigate a specific gravity model of the form f(R, Lm) = α R + Lmβ + γ, where the nonlinear dependence on the matter Lagrangian Lm introduces an effective curvature-matter interaction, leading to the non-conservation of the energy-momentum tensor. Using distance modulus data, we constrain the parameters through 2 minimization and Bayesian MCMC analysis, obtaining statistically robust best-fit values: H0 = 73.75 0.16~km\,s-1\,Mpc-1, λ = 0.262 0.007, and w = -0.005 0.001. This study presents a comprehensive and statistically rigorous comparison of three key early-Universe epochs: structure formation, recombination, and matter-radiation equality between the f(R,Lm) model and the standard cosmology. The model predicts an earlier onset of nonlinear structure formation (zcf(R,Lm) ≈ 25.6) and a higher matter-radiation equality redshift (zeqf(R,Lm) ≈ 4203) compared to (zeq CDM ≈ 2779), while maintaining consistency with the observed recombination redshift (zrec ≈ 1092). The recombination visibility function, derived using standard microphysical expressions with the modified expansion history, exhibits a slightly broader full width at half maximum, suggesting an extended photon decoupling period.