[34]      Ashlah M.-B.,†, Tu C.-Y., Rohman Y.-F., Firdaus A.-A., Choi W., and Sean W.-Y.*, “Development of Real-Time Estimation of Thermal and Internal Resistance for Reused Lithium-Ion Batteries Targeted at Carbon-Neutral Greenhouse Conditions”, Energies, 18(17), 4755 (2025). (SCI, IF: 3.0)

[33]      Kang Y.†, Ock D. Lee J., Lee J., Mok J., Go W., and Choi, W.*, “Optimizing Hydrate‑Based CO2 Capture in Saline Environments Using Low‑Dosage THF for Seawater Utilization”, Korean J. Chem. Eng., (2025). (SCI, IF: 3.0, Rank: 74/170 (43.2%) in Chemical Engineering)

[32]      Mok J.†, Kim S., Lee J., Choi W., and Seo Y.*, “Investigating the impact of N2 concentration on ternary gas hydrate formation for CH4 production and CO2 storage”, J. Mol. Liq., 429, 127578 (2025). (SCI, IF: 5.3, Rank: 6/40 (13.7%) in Physics, Atomic, Molecular & Chemical)

[31]      Lee J.†, Yun S., Mun S., Mok J.,  Choi W., and Seo Y.*, “Experimental and computational investigation of guest encapsulation and structural transformation behaviors in C3H8 hydrate − CO2 replacement for energy recovery and CO2 sequestration”, Fuel, 385, 134123 (2025). (SCI, IF: 6.7, Rank: 23/170 (13.2%) in Chemical Engineering)

[30]      Ock D.†, Kang Y., Lee J., Kim S., Mok J., Go W., and Choi, W.*, “Influence of Memory Effect on the Growth Kinetics of Thermodynamically Promoted CO2 + H2 Hydrate for Rapid Hydrate-Based Gas Separation”, Korean J. Chem. Eng., (2025). (SCI, IF: 3.0, Rank: 74/170 (43.2%) in Chemical Engineering)

[29]      Mok J.†, Lee J., Choi W., and Seo Y.*, “Complementary and competitive dynamics of CO2 and N2 in CH4–Flue gas replacement within natural gas hydrates”, Renew. Sustain. Energy Rev., 207, 114971 (2025). (SCI, IF: 16.3, Rank: 3/91 (2.7%) in Green & Sustainable Science & Technology)

[28]      Choi W.†, Mok J., Lee J., Lee Y., Lee J., and Seo Y.*, “Influence of CO2 injection rate and memory water on depressurization-assisted replacement in natural gas hydrates and the implications for effective CO2 sequestration and CH4 exploitation”, Energy, 309, 133130 (2024). (SCI, IF: 9.0, Rank: 3/76 (3.3%) in Thermodynamics)

[27]      Jamaludin M.†, Tsai Y.-C., Lin H.-T., Huang C.-Y., Choi W., Chen J.-G., and Sean W.-Y.*, “Modeling and Control Strategies for Energy Management in a Wastewater Center: A Review on Aeration”, Energies, 17(13), 3162 (2024). (SCI, IF: 3.0)

[26]      Chang T.-T.†, Choi W., Seo Y., Santosa A.F., Lin J.-J., Chen P.-Y., Tasi Y.-C., and Sean W.-Y. *, “Unlocking the ocean's potential: enhancing carbon capture through innovative replacement of methane hydrate by CO2”, Model. Earth Syst. Environ., 1-12 (2024). (SCI, IF: 2.7)

[25]      Mok J.†, Lee J., Choi W., Lee Y., and Seo Y.*, “Enhanced CH4–CO2 Replacement in Structure H Hydrates: Kinetics, Mechanisms, and Implications for CO2 Storage and CH4 Production”, ACS Sustain. Chem. Eng., 12, 8148-8155 (2024). (SCI, IF: 7.1, Rank: 21/170 (12.1%) in Chemical Engineering)

[24]      Mok J.†, Park M., Choi W., Kang K.C., Lee S., Lee J., and Seo Y.*, “Investigation of theoretical maximum water yield and efficiency-optimized temperature for cyclopentane hydrate-based desalination”, Water Res., 246, 120707 (2023). (SCI, IF: 13.400, Rank: 1/100 (0.5%) in Water Resources)

[23]     Lee J.†, Mok J., Choi W., and Seo Y.*, “Influence of structural transformation on guest exchange behavior in the sII hydrate – (CO2 + N2) replacement for energy recovery and CO2 sequestration”, Chem. Eng. J., 472, 144680 (2023). (SCI, IF: 15.100, Rank: 5/140 (3.2%) in Chemical Engineering)

[22]     Lee Y.†, Go W.†, Kim Y., Lim J., Choi W., and Seo Y.*, “Molecular guest exchange and subsequent structural transformation in CH4 – CO2 replacement occurring in sH hydrates as revealed by 13C NMR spectroscopy and molecular dynamic simulations”, Chem. Eng. J., 455, 140937 (2023). (SCI, IF: 16.744, Rank: 4/142 (2.5%) in Chemical Engineering)

[21]     Mok J.†, Choi W., Kim S., Lee J., and Seo Y.*, “NaCl-induced enhancement of thermodynamic and kinetic CO2 selectivity in CO2+ N2 hydrate formation and its significance for CO2 sequestration”, Chem. Eng. J., 451, 138633 (2023). (SCI, IF: 16.744, Rank: 4/142 (2.5%) in Chemical Engineering)

[20]      Choi W.†, Mok J., Lee J., Lee Y., Lee J., Sum A., and Seo Y.*, "Effective CH4 production and novel CO2 storage through depressurization-assisted replacement in natural gas hydrate-bearing sediment", Appl. Energy, 326, 119971 (2022). (SCI, IF: 11.446, Rank: 9/142 (5.9%) in Chemical Engineering)

[19]     Mok J.†, Choi W., and Seo Y.*, “Theoretically achievable efficiency of hydrate-based desalination and its significance for evaluating kinetic desalination performance of gaseous hydrate formers”, Desalination, 524, 115487 (2022). (SCI, IF: 11.211, Rank: 3/100 (2.5%) in Water Resources)

[18]      Mok J.†, Cho, W., Lee J., and Seo Y.*, “Effects of pressure and temperature conditions on thermodynamic and kinetic guest exchange behaviors of CH4 - CO2 + N2 replacement for energy recovery and greenhouse gas storage”, Energy, 232, 122153 (2022). (SCI, IF: 8.857, Rank: 3/63 (3.9%) in Thermodynamics)

[17]      Choi W.†, Lee J.†, Kim Y.-G., Kim H., Rhee T.S., Jin Y., Kim J.-H., Seo Y.*, "The impact of the abnormal salinity enrichment in pore water on the thermodynamic stability of marine natural gas hydrates in the Arctic region", Sci. Total Environ., 799, 149357 (2021). (SCI, IF: 10.753, Rank: 26/279 (9.1%) in Environmental Sciences)

[16]      Mok J.†, Lim J., Choi W., Yun S., Lee J., Ko G., and Seo Y.*, “Thermodynamic and structural features of chlorodifluoromethane (a sI-sII dual hydrate former) + external guest (N2 or CH4) hydrates and their significance for greenhouse gas separation”, Phys. Chem. Chem. Phys., 23, 15693-15701 (2021). (SCI, IF: 3.945, Rank: 9/36 (23.6%) in Physics, Atomic, Molecular & Chemical)

[15]      Mok J.†, Choi W., and Seo Y.*, “The dual-functional roles of N2 gas for the exploitation of natural gas hydrates: an inhibitor for dissociation and an external guest for replacement”, Energy, 232, 121054 (2021). (SCI, IF: 8.857, Rank: 3/63 (3.9%) in Thermodynamics)

[14]      Choi W.†, Go W., Lee Y., Mok J., and Seo Y.*, "Mechanism and kinetics of guest exchange in sII hydrate – flue gas replacement as revealed by experimental and computational approaches for hydrocarbon recovery and CO2 sequestration", Chem. Eng. J., 417, 128119 (2021). (SCI, IF: 16.744, Rank: 4/142 (2.5%) in Chemical Engineering)

[13]      Choi W.†, Mok J., Lee Y., Lee J., and Seo Y.*, "Optimal driving force for the dissociation of CH4 hydrates in hydrate-bearing sediments using depressurization", Energy, 223, 120047 (2021). (SCI, IF: 8.857, Rank: 3/63 (3.9%) in Thermodynamics)

[12]      Mok J.†, Choi W., and Seo Y.*, “Evaluation of kinetic salt-enrichment behavior and separation performance of HFC-152a hydrate-based desalination using an experimental measurement and a thermodynamic correlation”, Water Res., 193, 116882 (2021). (SCI, IF: 13.400, Rank: 1/100 (0.5%) in Water Resources)

[11]      Lee Y.†, Deusner C., Kossel E., Choi W., Haeckel M.*, and Seo Y.*, "Influence of CH4 Hydrate Exploitation Using Depressurization and Replacement Methods on Mechanical Strength of the Hydrate-Bearing Sediment", Appl. Energy, 277, 115569 (2020). (SCI, IF: 11.446, Rank: 9/142 (5.9%) in Chemical Engineering)

[10]      Choi W.†, Lee Y., Mok J., and Seo Y.*, "Influence of feed gas composition on structural transformation and guest exchange behaviors in sH hydrate - flue gas replacement for energy recovery and CO2 sequestration", Energy, 207, 118299 (2020). (SCI, IF: 8.857, Rank: 3/63 (3.9%) in Thermodynamics)

[9]      Choi W.†, Lee Y., Mok J., and Seo Y.*, "Influence of competitive inclusion of CO2 and N2 on sII hydrate flue gas replacement for energy recovery and CO2 sequestration", Environ. Sci. Tech., 54, 7562-7569 (2020). (SCI, IF: 11.357, Rank: 22/279 (7.7%) in Environmental Science)

[8]      Mok J.†, Choi W., and Seo Y.*, “Time-dependent observation of a cage-specific guest exchange in sI hydrates for CH4 recovery and CO2 sequestration”, Chem. Eng. J., 389, 124434 (2020). (SCI, IF: 16.744, Rank: 4/142 (2.5%) in Chemical Engineering)

[7]      Lim J.†, Choi W., Mok J., and Seo Y.*, "Kinetic CO2 selectivity in clathrate-based CO2 capture for upgrading CO2-rich natural gas and biogas", Chem. Eng. J., 369, 686-693 (2019). (SCI, IF: 16.744, Rank: 4/142 (2.5%) in Chemical Engineering)

[6]      Choi W.†, Lee Y., Mok J., Lee S., Lee JD., and Seo Y.*, "Thermodynamic and kinetic influences of NaCl on HFC-125a hydrates and their significance in gas hydrate-based desalination", Chem. Eng. J., 358, 598-605 (2019). (SCI, IF: 16.744, Rank: 4/142 (2.5%) in Chemical Engineering)

[5]      Lee Y.†, Choi W., Seo Y., Lee J., Lee J., and Seo Y.*, "Structural transition induced by cage-dependent guest exchange in CH4 + C3H8 hydrates with CO2 injection for energy recovery and CO2 sequestration", Appl. Energy, 228, 229-239 (2018). (SCI, IF: 11.446, Rank: 9/142 (5.9%) in Chemical Engineering)

[4]      Kim E.†, Choi W., and Seo Y.*, "Thermodynamic phase equilibria and cage occupancy of NF3 hydrate", Fluid Phase Equilib., 471, 55-60 (2018). (SCI, IF: 2.745, Rank: 29/63 (45.2%) in Thermodynamics)

[3]      Lim J.†, Choi W., Mok J., and Seo Y.*, "Clathrate-based CO2 capture from CO2 rich natural gas and biogas", ACS Sustainable Chem. Eng., 6, 5627-5635 (2018). (SCI, IF: 9.224, Rank: 13/142 (8.8%) in Chemical Engineering)

[2]      Lee Y.†, Choi W., Shin K.*, and Seo Y.*, "CH4 - CO2 replacement occurring in sII natural gas hydrates for CH4 recovery and CO2 sequestration", Energy Convers. Manag., 150, 356-364 (2017). (SCI, IF: 11.533, Rank: 3/138 (1.8%) in Mechanics)

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