Time | Paper ID | Title / Authors | Keywords | Topic code | Ack. number |
---|---|---|---|---|---|
Separation processes | |||||
(9:12–10:24) (Chair: No data , No data ) | |||||
E02 | Separation properties of carbon dioxide by silicalite membranes prepared on porous SUS tube | silicalite membrane carbon dioxide separation property | 4-a | 62 | |
E03 | Search of zeolite particles introduced on porous SUS tubes for preparation of palladium thin membranes | Pd thin membrane zeolite particle porous SUS tube | 4-a | 63 | |
E04 | Preparation of dense Pd membranes by vacuum-assisted electroless plating on porous SUS tube with spherical silica particles | Dense Pd membrane on porous SUS tube Vacuum-assisted electroless plating Spherical silica particle | 4-a | 65 | |
E05 | Separation of organic liquids through silica membranes | aceticacid iodomethane acetaldehyde | 4-a | 67 | |
E06 | Fabrication of polyamide-TFC membrane using porous ceramic substrate | Polyamide Ceramic membrane Nanofiltration | 4-a | 146 | |
E07 | Examination of Zeolite-TiO2 composite membrane aiming at decomposition of dissolved organic matter | membrane Zeolite TiO2 | 4-a | 286 | |
Break | |||||
Separation processes | |||||
(10:36–11:36) (Chair: No data , No data ) | |||||
E09 | Adsorption characteristics of acid clay as adsorbent for caffeine | caffeine acid clay | 4-e | 102 | |
E10 | Characterization of Multimodal Chromatographic resins using Design of Experiments | Multimodal chromatography Design of Experiments protein adsorption | 4-e | 299 | |
E11 | Development of Zn plating wastewater by adsorption separation system using ion exchange/chelate fibers | Adsorption separation Ion exchange/chelate fibers Plating wastewater | 4-e | 201 | |
E12 | Preparation of activated carbon from waste orange peels by microwave heating | Microwave Activated carbon Orange peel | 4-e | 273 | |
E13 | Applying chlorophyll to sunscreen cream | Synergy Sunscreen cream Persistence | 14-e | 137 | |
Lunch break | |||||
Supercritical fluid | |||||
(13:00–14:24) (Chair: No data , No data ) | |||||
E21 | Mechanochemical effect on cocrystal formation in high-pressure CO2 | high-pressure CO2 mechanochemical effect cocrystallization | 8-e | 199 | |
E22 | Fabrication of visible light responsive photocatalyst by supporting CuO fine particles on TiO2 thin film using supercritical fluid deposition | supercritical fluid deposition visible light responsive photocatalyst | 8-e | 141 | |
E23 | Effects of equipment factors on production of microparticles by supercritical anti-solvent recrystallization (SAS) in micro-space | SAS Micro device Sulfathiazole | 8-e | 265 | |
E24 | Preparation of ionic liquid impregnated mesoporous silica material using supercritical fluid method | Supercritical carbon dioxide Mesoporous silica Ionic liquid | 8-e | 184 | |
E25 | Measurement and modeling of adsorption equilibria of ester VOCs in supercritical CO2 for regeneration of high-performance activated carbon | Supercritical carbon dioxide Activated carbon Adsorption | 8-c | 197 | |
E26 | Heat transport behavior of supercritical nano fluid | supercritical water nano fluid heat transfer | 8-b | 59 | |
E27 | Effect of coexisting ions and pH on the decomposition of dibutyl phosphate in high-pressure and high-temperature water | Dibutyl phosphate Coexisting ions Reaction rate analysis | 8-d | 158 | |
Break | |||||
Supercritical fluid | |||||
(14:36–16:00) (Chair: No data , No data ) | |||||
E29 | Development of Medical Nanoparticles using The Technology of Extractions of Emulusions | Nanoparticles Supercritical carbon dioxide Emulsion | 8-e | 274 | |
E30 | Extraction of Flavones from natural plants | High pressure carbon dioxide Luteolin Apigenin | 8-c | 275 | |
E31 | Development of New Pesticides | Pyriproxyfen Supercritical carbon dioxide Pesticides | 8-e | 276 | |
E32 | Development of Medical Devices by PGSS Method | Supercritical carbon dioxide Caffeine Micro coating | 8-e | 277 | |
E33 | Microencapsulation of Levofloxacin | Microcapsule Supercritical Carbon Dioxide Levofloxacin | 8-e | 278 | |
E34 | Liquefaction of Sake Lees by Subcritical Water Treatment and Evaluation as a Vinegar Manufacturing Additives | Subcritical Water Liquefaction Sake Lees | 8-f | 202 | |
E35 | Decomposition of dibutyl phosphate in high temperature and high pressure water using metal oxide catalysts | dibutyl phosphate high temperature and high pressure water solid catalyst | 8-d | 157 |