Last modified: 2024-12-13 11:36:26
Time | Paper ID | Title / Authors | Keywords | Topic code | Ack. number |
---|---|---|---|---|---|
Hall F, Day 1 | |||||
(13:00–14:20) (Chair: | |||||
F113 | Evaluation of alkane synthesis process from C1 compounds via CH3SH | Methanethiol Alkane synthesis Sulfur | 5-a | 552 | |
F114 | Structured catalyst system for rapidly transforming GHG: Performance acceleration effect by swirl flow | Structured catalyst system Methanation Reverse water gas shift | 5-a | 417 | |
F115 | [Featured presentation] Structured catalyst system for rapidly transforming GHG: Application to green process | Structured catalyst system Dry reforming Solid carbon capture | 5-a | 418 | |
F116 | Active sites of CO2 methanation on Ni/CeO2 prepared by flame spray pyrolysis | CO2 methanation Ni catalyst CeO2 | 5-a | 493 | |
(14:20–14:40) (Chair: | |||||
F117 | Reaction Kinetics of CO2 Capture and Conversion over Dual-Function Materials | dual-function materials CO2 capture and utilization reaction kinetics | 5-a | 612 | |
(15:00–15:40) (Chair: | |||||
F119 | Development of HNb3O8/g-C3N4 nanosheet composite photocatalytic membranes with two-dimensional heterostructured nanochannels | nanosheet photocatalytic membrane reactor heterostructured nanochannel | 5-a | 576 | |
F120 | Reaction mechanism and kinetics of isoparaffin gas-phase selective oxidation with water and oxygen over transition metal oxide catalysts | green oxidation metal oxide catalyst kinetic analysis | 5-a | 464 | |
(15:40–17:00) (Chair: | |||||
F121 | Investigation of promoter in plasma DRM by Co based catalyst | Co based catalyst Plasma catalyst CO2 capture and utilization | 5-a | 663 | |
F122 | Development of Hybrid Kinetic Model Applying Machine Learning for Liquid Phase Photocatalytic Reaction | Photocatalyst Kinetics Machine learning | 5-a | 693 | |
F123 | Machine Learning-assisted analysis of NO adsorption and dissociation on PdRuIr ternary nanoparticle alloy | machine learning nanoparticle alloy catalysis | 5-a | 285 | |
F124 | Improving efficiency of reaction mechanism exploration using chemical reaction neural network and its application to glycerol oxidation reaction | chemical reaction neural network kinetic model glycerol oxidation | 5-a | 325 | |
Hall F, Day 2 | |||||
Organized Session (CVD Reactions Section, Division of Chemical Reaction Engineering) | |||||
(9:00–10:00) (Chair: | |||||
F201 | Reaction Rate Equation Determination of Chemical Vapor Deposited Bismuth-based Perovskite Thin Film | Chemical vapor deposition Methylammonium bismuth iodide Perovskite solar cell | 5-h | 686 | |
F202 | Evaluation of Reactive sputtered MAX alloy thin films with reducing gas | sputtering MAX-phase | 5-h | 787 | |
F203 | Rate analysis of carbon CVD from hydrocarbons with different degrees of unsaturation | CVD carbon coking | 5-h | 785 | |
(10:00–11:00) (Chair: | |||||
F204 | Exploring the large-area graphene CVD conditions by machine learning assisted image analysis | Graphene Chemical vapor deposition Machine learning | 5-i | 302 | |
F205 | Stable and continuous synthesis of carbon nanotubes by floating catalyst CVD with fluid mixing control | carbon nanotube chemical vapor deposition continuous process | 5-h | 225 | |
F206 | Reduction of reaction mechanism of SiC-CVI | SiC-CVI CH3SiCl3 Reduced model | 5-h | 562 | |
(11:00–12:00) (Chair: | |||||
F207 | Research on improving uniformity in furnace and high speed SiC infiltration in the production of SiC-CMC using Chemical Vapor Infiltration method. | SiC CVI CVD | 5-h | 233 | |
F208 | Exploration of exhaust gas reforming conditions to improve yield and reduce by-product formation in SiC-CVI with high MTS partial pressure | CVI SiC Recycling | 5-h | 633 | |
F209 | Strategy for CVI process development in SiCf/SiC-CMC production | CVI SiC Process design | 5-h | 634 | |
(13:20–14:20) (Chair: | |||||
F214 | Influence of binder added zeolite catalyst on hydrotreating of vegetable oil | binder vegetable oil zeolite | 5-a | 628 | |
F215 | Saccharification of Cellulose by Using Mesoporous Carbons | Mesoporous carbon Saccharification Cellulose | 5-a | 671 | |
F216 | Reactive extraction process of lignin under hydrothermal condition: a use of slug flow of qater/organic biphasic system | vanilin slug flow hydrothermal reaction | 5-d | 714 | |
(14:20–14:40) (Chair: | |||||
F217 | [The SCEJ Award for Outstanding Young Researcher] Mechanistic understanding of catalytic reaction utilizing automated flow reactor systems | The SCEJ Award for Outstanding Young Researcher | 0-c | 745 | |
(15:00–16:00) (Chair: | |||||
F219 | Polymer immobilization catalysts using machine learning methods | Polymer Immobilized Catalyst Machine Learning Pd | 5-f | 717 | |
F220 | Kinetic analysis of Claisen rearrangement using near-infrared spectroscopy and transient flow method | automated flow reactor NIR kinetic analysis | 5-f | 136 | |
F221 | Evaluation of the mass transfer model and analysis of the error causes for the Taylor flow reactor with hydrogenation reaction | Taylor flow Gas-Liquid reaction Mass transfer | 5-f | 406 | |
(16:00–17:00) (Chair: | |||||
F222 | Oxygen Transport Analysis in Meso Pores of Carbon Support for Polymer Electrolyte Fuel Cells by Reactive Molecular Dynamics Method | Polymer Electrolyte Fuel Cell Catalyst Layer Reactive Molecular Dynamics Method | 5-a | 52 | |
F223 | Graphical Analysis of Infinite Number of First-order Parallel Reactions | Kinetic analysis DAEM Activation energy | 5-i | 307 | |
F224 | Modeling of Autocatalytic Reaction by Cylindrical Particle with Finite Length | cylindrical particle with finite length autocatalytic reaction reaction-diffusion equation | 5-i | 98 | |
Hall F, Day 3 | |||||
(10:20–12:00) (Chair: | |||||
F305 | Efficient production of chitin-oligosaccharides using a vibratory disc mill and clay reagents | chitin biorefinery mechanochemical reaction clay | 5-g | 164 | |
F306 | Predicting bed agglomeration in fluidized-bed combustion of biomass fuels | agglomeration fluidized-bed combustion biomass fuels | 5-g | 83 | |
F307 | Development of catalytic process for the synthesis of aromatic compounds from bioethanol | Bioethanol aromatic compound catalytic process | 5-g | 499 | |
F308 | Biomass pretreatment to enhance the pyrolysis reaction at low temperature | Biomass Pyrolysis Pretreatment | 5-g | 544 | |
F309 | Development of sustainable formic acid/AlCl3/choline chloride catalyzed levulinic acid production process using byproducts | Levulinic acid Choline chloride Techno-economic analysis | 5-g | 288 | |
Hall G, Day 3 | |||||
Organized Session (CVD Reactions Section, Division of Chemical Reaction Engineering) | |||||
(9:00–10:40) (Chair: | |||||
G301 | Quantitative Analysis of Trimethylaluminum Physisorption for ALD | Atomic Layer Depositon Quartz Crystal Microbalance Surface Adsorption | 5-h | 383 | |
G302 | Study of ZrN thin film formation process using atomic layer deposition | ZrN ALD TEMAZ | 5-h | 273 | |
G303 | Development of Molybdenum Atomic Layer Deposition Process for Next Generation of ULSI Interconnect | Molybdenum ALD low resistivity | 5-h | 123 | |
G304 | Silicon Nitride ALD Process Using High Purity Hydrazine | Siicon Nitride Atomic Layer Deposition Incubation Cycle | 5-h | 109 | |
G305 | Investigation of Co Thin Film Thermal Atomic Layer Etching Process | ALE atomic layer eching cobalt | 5-h | 516 | |
(10:40–12:00) (Chair: | |||||
G306 | Investigation of Area Selective Co-ALD process utilizing in-situ observation of reflectance intensity. | ALD in-situ observation reflectance | 5-h | 232 | |
G307 | Investigation of Continuous Cu Film Formation Process on Polymer | Atomic Layer Depoition Copper on Polymer | 5-h | 531 | |
G308 | Surface activation of the copper surface by VUV-Redox method using xenon excimer lamp | VUV-Redo Surface activation | 5-h | 786 | |
G309 | CFD Simulation Study on factors influencing AlN compound single crystal growth | MOCVD CFD III-V compound | 5-h | 683 | |
CVD reaction subdivision encouragement award ceremony |
Technical program
Technical sessions (Wide)
(For narrow screen)
Session programs
Search in technical program
SCEJ 89th Annual Meeting (Sakai, 2024)