Grigorash, DariaDariaGrigorashMüller, SimonSimonMüllerHeid, EstherEstherHeidNeese, FrankFrankNeeseLiakos, Dimitrios G.Dimitrios G.LiakosRiplinger, ChristophChristophRiplingerGarcia-ratés MiquelParicaud, PatricePatriceParicaudHalfdan Stenby, ErlingErlingHalfdan StenbySmirnova, IrinaIrinaSmirnovaYan, WeiWeiYan2025-10-222025-10-222025-07-09Chemical Engineering Science 319: 122170 (2026)https://hdl.handle.net/11420/57991OpenCOSMO-RS is an open-source predictive thermodynamic model that can be applied to a broad range of systems in various chemical and biochemical engineering domains. This study focuses on improving openCOSMO-RS by introducing a new dispersion term based on atomic polarizabilities. We evaluate different methods for processing polarizability data, including scaling and combining it to compute segment-segment dispersion interaction energies, with a focus on halocarbon systems. The results demonstrate that the modified model outperforms our previous method developed in the first part of this work Grigorash et al. (2024), while at the same time requiring fewer adjustable parameters. The approach was applied to a broad dataset of over 50,000 data points, consistently increasing the accuracy across a variety of data types. These findings suggest that atomic polarizability is a valuable descriptor for refining dispersion interactions in predictive thermodynamic models.en0009-25092025Elsevierhttps://creativecommons.org/licenses/by/4.0/COSMO-RSDispersionParametrizationPolarizabilityTechnology::660: Chemistry; Chemical EngineeringJournal Articlehttps://doi.org/10.15480/882.1599410.1016/j.ces.2025.12217010.15480/882.15994Journal Article