Day 1 | |||||
---|---|---|---|---|---|
Time | Paper ID | Title / Authors | Keywords | Topic code | Ack. number |
Supercritical fluid | |||||
(14:00–15:20) ( Haruki M.) | |||||
L116 | Effect of hot compressed water properties on solid acid catalyzed reaction | Hot compressed water Solid acid catalyst Effect of water properties | 8-d | 230 | |
L117 | Hydrothermal oxidative degradation of lignin into organic acids | lignin oxidative degradation organic acid | 8-d | 815 | |
L118 | Transformation of woody biomass by carboxylic acid in high-pressure and high-temperature water | high-pressure and high-temperature water biomass | 8-d | 491 | |
L119 | A combined effect of supercritical CO2/water medium on the conversion of 5-hydroxymethylfurfural to 2, 5-dimethylfuran | hydrogenation supercritical carbon dioxide 5-hydroxymethylfurfural | 8-d | 39 | |
Break | |||||
(15:40–17:20) ( Uchida H., Hasegawa I.) | |||||
L121 | Sub- and Supercritical Fluid Extraction of Anticancer Compounds from Substandard Seaweeds | marine biomass subcritical water supercritical carbon dioxide | 8-c | 822 | |
L122 | Substituents effects on the catalyst of the photoreduction of CO2 in scCO2 | photoreduction scCO2 Re catalyst | 8-d | 492 | |
L123 | Development of imprint technology using carbon dioxide | imprint carbon dioxide polymer | 8-e | 85 | |
L124 | Fabrication of Nanocomposite Thermal Insulating Materials via Foam Extrusion of Polystylene-Silicon Alkoxide-CO2 ternary system | Polymer nanocomposite High Pressure Phase Diagram Thermal Insulating Materials | 8-e | 186 | |
L125 | Deposition of polyimide thin film using supercritical carbon dioxide | supercritical carbon dioxide polyimide deposition | 8-e | 238 | |
Day 2 | |||||
Time | Paper ID | Title / Authors | Keywords | Topic code | Ack. number |
Chemical Industry Technology Forum -(Nano-fluid)- | |||||
(9:00–12:00) ( Adschiri Tadafumi, Kanie Kiyoshi) | |||||
L201 | [Requested talk]Science and Application of Nano-fluid: their old-style novel science and technology | nanofluid nanoparticle nanowire | F-1 | 585 | |
L202 | [Requested talk]DNS for electrophoresis of colloidal particles in DC/AC electric fields | electrophoresis colloid hydrodynamics | F-1 | 505 | |
L203 | [Requested talk]Science of nanofluid: Synthesis of organic-modified nanoparticles and properties of nanofluid | organic-modified nanoparticles supercritical hydrothermal synthesis viscosity | F-1 | 593 | |
L204 | [Requested talk]Structure Formation of Dense Colloidal Solutions under Flow Field and Drying Field | Nonequilibrium Phase Transition Kneading Shear Thickening | F-1 | 427 | |
L205 | Modeling of interaction among dispersed particles considering transport and adsorption of solute | dispersion direct numerical simulation solute adsorption | F-1 | 134 | |
L206 | Numerical simulation of dispersion and aggregation behaviors of organic-modified nanoparticles | organic-modified nanoparticles numerical simulation Dispersion and aggregation | F-1 | 745 | |
L207 | Classification by Coagulation Phenomena of Nanoparticles in Addition of Poor Solvent | nanoparticles classification size-selective precipitation | F-1 | 807 | |
L208 | [Requested talk]Nano-fluid Application: preparation and application of Ag nano-wire on nano-cellulose as a substrate | nanowire nanofluid printing | F-1 | 404 | |
L209 | [Requested talk]Wet preparation of metallic copper fine particles and applications for electroconductive materials (Faculty of Engineering, Hokkaido U.) Yonezawa Tetsu | copper electrocondcutive packaging | F-1 | 411 | |
Lunch break | |||||
(13:00–16:20) ( Muramatsu Atsushi, Takami Seiichi) | |||||
L213 | [Requested talk]Liquid Phase Synthesis of TransparentConductive Oxide Nanoparticles with Low Conductivity and the Nano-ink Property | Transparent Conductive Oxide Nano-ink Nanoparticle | F-1 | 412 | |
L214 | Preparation of Nanofluids Based on Dendron-Modified Nanospheres and Analysis of Self-Organized Nano Structures | Nanofluid Dendron Self-Organization | F-1 | 440 | |
L215 | Oxidation Resistance of Iron-Oxide-Coated Fe nanoparticles | nanoparticle soft magnetic phase oxidation resistance | F-1 | 604 | |
L216 | Thermophysical properties and heat transfer performance of mono-dispersed nanofluids | nanofluid thermal conductivity heat transfer performance | F-1 | 621 | |
L217 | [Requested talk]Continuous production of finer particle using wet-type super atomizer | nano particle turblent flow wet type atomizer | F-1 | 494 | |
Break | |||||
L219 | Reaction control for synthesis of photoluminescent nanocarbon with electrospray microreactor | nanocarbon electrospray microreactor | F-1 | 466 | |
L220 | Electrolyte properties of nanoscale confined ionic liquids and their application to lithium ion batteries | Ionic Liquid nanoparticles lithium ion battery | F-1 | 325 | |
L221 | [Requested talk]Organic micronization process in nanofluid containing supercritical fluid phase | Supercritical fluid Nanoparticle Anti-solvent | F-1 | 524 | |
L222 | [Requested talk]Application of Nanofluids: Supercritical Technology | nanofluid supercritical water application | F-1 | 533 | |
L223 | Discussion time | nanofluid discussion | F-1 | 854 | |
Day 3 | |||||
Time | Paper ID | Title / Authors | Keywords | Topic code | Ack. number |
Supercritical fluid | |||||
(9:20–10:20) ( Kawanami Hajime) | |||||
L302 | Micronization of lutein from marigold flower by supercritical anti solvent | lutein micronization supercritical anti solvent | 8-e | 473 | |
L303 | Kinetic study for supercritical fluid deposition of TiO2 using micro- and macro- cavity | TiO2 supercritical fluid deposition kinetic | 8-e | 112 | |
L304 | Fabrication of 3D-CIS solar cell structure by conformal deposition of CuInS2 on TiO2 nanoporous films using supercritical fluid | Supercritical Fluid Solar Cell Conformal deposition | 8-e | 368 | |
Break | |||||
(10:40–12:00) ( Kawasaki S) | |||||
L306 | Phase equilibrium calculation for supercritical carbon dioxide system by equation of state based on hole theory | supercritical carbon dioxide hole theory phase equilibrium | 8-b | 641 | |
L307 | Elucidation of Co-solvent Effects of Methylparaben on the Production of Theophylline Nanoparticles Using the RESS-SC Technique | RESS-SC technique Theophylline nanoparticle production Solid cosolvent effects | 8-e | 799 | |
L308 | Direct exfoliation synthesis of graphene materials by supercritical fluid process | graphene supuercritical fluid mass production technique | 8-e | 498 | |
L309 | A method to produce highly reduced graphene oxide | graphene oxide reduction supercritical | 8-e | 518 | |
Break | |||||
(15:20–16:40) ( Tomai Takaaki) | |||||
L320 | Production of acetaminophen/cyclodextrin nano-particles using supercritical anti-solvent technique | supercritical fluid anti-solvent particle | 8-g | 318 | |
L321 | Micronization of carotenoid and cyclodextrin inclusion complex using supercritical antisolvent | Supercritical antisolvent carotenoid cyclodextrin | 8-g | 444 | |
L322 | Particle removal in liquid or supercritical CO2 by sintered metallic filters | supercritical CO2 particle | 8-g | 326 | |
L323 | Dissolution behavior of metal from reactor tube into supercritical water at high pressure up to 100 MPa | metal dissolution supercritical water pressure | 8-g | 97 |