- 열물성 연구실 (Thermodynamics Properties Lab)
- 02-705-8918 (R603A)
- limjs@sogang.ac.kr
- http://scf.sogang.ac.kr
- 고려대학교 공학박사(1993)
임종성Jong Sung Lim
Research Areas
Thermodynamics and Green Process for Separation.
Research Interests
NANOPARTICLES, SYNTHESIS, AND RECYCLING USING SUPERCRITICAL FLUIDS.
Supercritical nanoparticle manufacturing is very effective in refining heat-sensitive drugs, proteins, and vitamins without residual solvents and is being researched and developed in a wide range of fields, such as drug particles and biodegradable polymers (PLAs) for DDS(Drug Delivery Systems). In our laboratory, we are researching the process of manufacturing nanoparticles using RESS (Rapid Expansion of Supercritical Solution) and SAS (Supercritical Anti Solvent).
MEASUREMENT OF THERMODYNAMIC PROPERTIES, PHASE EQUILIBRIUM OF VARIOUS MIXTURES, AND OPTIMIZATION OF PROCESS MODELING.
The vapor-liquid phase equilibrium and liquid-liquid phase equilibrium measurement of various mixtures under reduced pressure, normal pressure, high pressure, low temperature, and high-temperature conditions provide data on macroscopic phase behavior. The phase equilibrium data obtained this way becomes essential information for developing new high-efficiency separation processes. In our laboratory, vapor-liquid and liquid-liquid phase equilibria of various mixtures are measured, and various thermodynamic models are optimized using the measured data for accurate predicting under various conditions.
MEASUREMENT OF THE PHYSICAL PROPERTIES AND SOLUBILITY OF IONIC LIQUIDS FOR CARBON DIOXIDE CAPTURE.
Carbon dioxide generated from fossil fuels causes global warming, and CCS(Carbon dioxide Capture and Storage) technology are being used to reduce this. Ionic liquids are emerging as next-generation carbon dioxide absorbers due to their chemical stability, low corrosivity, low vapor pressure, and high carbon dioxide solubility. Our laboratory is conducting research on the development of carbon dioxide adsorption technology by experimentally measuring the solubility of carbon dioxide according to various ionic liquids.
Supercritical nanoparticle manufacturing is very effective in refining heat-sensitive drugs, proteins, and vitamins without residual solvents and is being researched and developed in a wide range of fields, such as drug particles and biodegradable polymers (PLAs) for DDS(Drug Delivery Systems). In our laboratory, we are researching the process of manufacturing nanoparticles using RESS (Rapid Expansion of Supercritical Solution) and SAS (Supercritical Anti Solvent).
MEASUREMENT OF THERMODYNAMIC PROPERTIES, PHASE EQUILIBRIUM OF VARIOUS MIXTURES, AND OPTIMIZATION OF PROCESS MODELING.
The vapor-liquid phase equilibrium and liquid-liquid phase equilibrium measurement of various mixtures under reduced pressure, normal pressure, high pressure, low temperature, and high-temperature conditions provide data on macroscopic phase behavior. The phase equilibrium data obtained this way becomes essential information for developing new high-efficiency separation processes. In our laboratory, vapor-liquid and liquid-liquid phase equilibria of various mixtures are measured, and various thermodynamic models are optimized using the measured data for accurate predicting under various conditions.
MEASUREMENT OF THE PHYSICAL PROPERTIES AND SOLUBILITY OF IONIC LIQUIDS FOR CARBON DIOXIDE CAPTURE.
Carbon dioxide generated from fossil fuels causes global warming, and CCS(Carbon dioxide Capture and Storage) technology are being used to reduce this. Ionic liquids are emerging as next-generation carbon dioxide absorbers due to their chemical stability, low corrosivity, low vapor pressure, and high carbon dioxide solubility. Our laboratory is conducting research on the development of carbon dioxide adsorption technology by experimentally measuring the solubility of carbon dioxide according to various ionic liquids.
Selected Publications
Hyun Ji Kim, Joon-Hyuk Yim, Jong Sung Lim, “Measurement and correlation of ternary system {water + 2,3-butanediol + 2-methyl-1-pentanol} and {water + 2,3-butanediol + 3-methyl-1-butanol} liquid-liquid equilibrium data”, Fluid Phase Equilib 518 (2020) 112639.
Joon-Hyuk Yim, Seung Jae Ha, Jong Sung Lim, ‘Measurement and correlation of CO2 solubility in 1-butyl-3-methylimidazolium ([BMIM]) cation-based ionic liquids: [BMIM][Ac], [BMIM][Cl], [BMIM] [MeSO4]’ J. Supercrit. Fluids 138 (2017) 73–81.
Ji Eun Kim, Hak Joo Kim, Jong Sung Lim, “Solubility of CO2 in ionic liquids containing cyanide anions: [c2mim][SCN], [c2mim][N(CN)2], [c2mim][C(CN)3]” Fluid Phase Equilib 367(2014) 151-158.
Hyun Cho, Joon-Hyuk. Yim, Jong Sung Lim, “Measurement of VLE data of carbon dioxide (CO2) + methyl iodide (CH3I) system for the direct synthesis of dimethyl carbonate using supercritical CO2 and methanol" J. Supercrit. Fluids 81 (2013) 7-14.
Hye Min Yu, Joon-Hyuk Yim, Kyu Yong Choi, Jong Sung Lim, “Fabrication and Characterization of Titania Inverse Opals using Supercritical Carbon Dioxide” J. Supercrit. Fluids 67 (2012) 71-75.
Joon-Hyuk Yim, Seung Jae Ha, Jong Sung Lim, ‘Measurement and correlation of CO2 solubility in 1-butyl-3-methylimidazolium ([BMIM]) cation-based ionic liquids: [BMIM][Ac], [BMIM][Cl], [BMIM] [MeSO4]’ J. Supercrit. Fluids 138 (2017) 73–81.
Ji Eun Kim, Hak Joo Kim, Jong Sung Lim, “Solubility of CO2 in ionic liquids containing cyanide anions: [c2mim][SCN], [c2mim][N(CN)2], [c2mim][C(CN)3]” Fluid Phase Equilib 367(2014) 151-158.
Hyun Cho, Joon-Hyuk. Yim, Jong Sung Lim, “Measurement of VLE data of carbon dioxide (CO2) + methyl iodide (CH3I) system for the direct synthesis of dimethyl carbonate using supercritical CO2 and methanol" J. Supercrit. Fluids 81 (2013) 7-14.
Hye Min Yu, Joon-Hyuk Yim, Kyu Yong Choi, Jong Sung Lim, “Fabrication and Characterization of Titania Inverse Opals using Supercritical Carbon Dioxide” J. Supercrit. Fluids 67 (2012) 71-75.
Professional Experience
◦ Professor, Sogang University (2004. 3 - present)
◦ Visiting Professor, University of Maryland (2010)
◦ Post Doc, Johns Hopkins University (1999)
◦ Senior and Principal Research Engineer, KIST (1994 - 2004)
◦ Visiting Professor, University of Maryland (2010)
◦ Post Doc, Johns Hopkins University (1999)
◦ Senior and Principal Research Engineer, KIST (1994 - 2004)