Constraining a $f(R, L_m)$ Gravity Cosmological Model with Observational Data

We investigate a spatially flat FLRW cosmological model within modified gravity, defined by the function \( f(R, L_m) = \alpha R + L_m^\beta + \gamma \), where \( L_m \) is the matter Lagrangian density. The resulting Friedmann equations yield the Hubble parameter: \[ H(z) = H_0 \sqrt{(1 - \lambda) + \lambda (1 + z)^{3(1 + w)}}, \] with \( \lambda = \frac{\gamma}{6\alpha H_0^2} + 1 \) and \( w = \frac{\beta(n - 2) + 1}{2\beta - 1} \). The parameter \( n \), linked to the equation of state \( p = (1 - n)\rho \), allows the model to account for different cosmological epochs. Using a Bayesian MCMC method, we constrain the model parameters with data from cosmic chronometers, the Pantheon+ Supernovae sample, BAO, and CMB shift parameters. The best-fit values obtained are \( H_0 = 72.773^{+0.148}_{-0.152} \, \text{km/s/Mpc} \), \( \lambda = 0.289^{+0.007}_{-0.007} \), and \( w = -0.002^{+0.002}_{-0.002} \), all at the 1\(\sigma\) confidence level. The model predicts a transition redshift \( z_t \approx 0.76 \) for the onset of acceleration and an estimated universe age of 13.21 Gyr. The relatively higher value of \( H_0 \) compared to Planck 2018 suggests a possible resolution to the Hubble tension. Assuming \( \rho_0 = 0.534 \times 10^{-30} \, \text{g/cm}^3 \) and \( n = 1 \), the constants are found to be \( \beta = 1.00201 \), \( \alpha = 512247 \), and \( \gamma = -1.215 \times 10^{-29} \). We also compute the Bayesian Information Criterion (BIC) to compare this model to the standard \(\Lambda\)CDM. A small BIC difference (\( \Delta \text{BIC} = 0.16 \)) indicates similar statistical support. Thus, the \( f(R, L_m) \) model stands as a consistent and viable alternative to \(\Lambda\)CDM, offering insights into late-time cosmology.