A modified non-local free energy density functional theory (NDFT) model, with the consideration of the nonadditivity term of solid-fluid and fluid-fluid interactions and finite pore wall thickness (≈2 layers), was developed to model the confined fluid mixtures in slit pore. This improved NDFT approach, com- bining with the pore size distribution (PSD) analysis of adsorbent material can be applied to predicting the adsorption equilibria of high-pressure gas mixtures on activated carbon. Compared with the con- ventional NDFT method, this new approach partly improves the correlation performance of adsorption equilibrium for pure species and increases the reliability of the PSD analysis. For the mixtures, CH4/N2 and CO2/N2, a relatively improved performance has been observed for the adsorption equilibrium pre- diction of the mixtures under high-pressure conditions, especially for the weakly adsorbed species. A modified non-local free energy density functional theory (NDFT) model, with the consideration of the nonadditive term of solid-fluid and fluid-fluid interactions and finite pore wall thickness (≈ 2 layers), was developed to model the confined fluid fluid This improved NDFT approach, com- bining with the pore size distribution (PSD) analysis of adsorbent material can be applied to predicting the adsorption equilibria of high-pressure gas mixtures on activated carbon. Compared with the method Conventional NDFT method , this new solution partly improves the correlation performance of adsorption equilibrium for pure species and increases the reliability of the PSD analysis. For the mixtures, CH4 / N2 and CO2 / N2, a relatively improved performance has been observed for the adsorption equilibrium pre- diction of the mixtures under high-pressure conditions, especially for the weakly adsorbed species.