Abstract
Recent advances in computational capabilities have revolutionized the modeling of nanoporous carbons, enabling a transition from idealized pore descriptions to versatile three-dimensional molecular models. This review traces the evolution from traditional continuous potential methods and elementary pore models to modern simulation techniques that generate realistic carbon structures incorporating surface heterogeneity, pore connectivity, and framework flexibility. We examine various approaches including Hybrid Reverse Monte Carlo, Quench Molecular Dynamics, and Annealed Molecular Dynamics methods, discussing their relative strengths and limitations. Particular attention is given to the choice of interatomic potentials and their impact on structural predictions. The development of million-atom models captures long-range ordering effects previously inaccessible to simulation. Applications of the 3D models demonstrate their capability to predict adsorption behavior quantitatively and provide improved characterization of practical carbons through novel methods such as 3D-VIS and APDM. Recent hybrid MD/MC approaches incorporate the effects of structure flexibility and offer new insights into adsorbate-induced structural changes. This review highlights how advancing computational methods are bridging the gap between molecular-level understanding and practical applications in the carbon materials design and modeling of adsorption processes.