SCEJ

25th SCEJ Students Meeting (online, 2023)

Session programs

Japanese page

Chemical reaction engineering

E01-E07, E09-E14, E20-E25, E27-E33, F02-F07

Most recent update: 2023-03-16 14:37:10
TimePaper
ID
Title / AuthorsKeywordsTopic codeAck.
number
Hall E
(9:20–10:44) (Chair: Takahashi Atsushi, Tada Shoheiˇˇ)
9:209:32E01Methanol synthesis by CO2 hydrogenation over Cu-supported ZSM-5 catalyst
(Tokyo Tech) *Awano K., Tago T., Kimura K., Kanomata R., Yokoi T., Yasuda S., Matsumoto T., (Kyoto U.) Fujitsuka H., (Tokyo U.) Wakihara T., Raquel S.
CO2 hydrogenation
Methanol synthesis
Zeolite supported Cu catalyst
5-a249
9:329:44E02Improving Production Efficiency of Biodiesel Fuel from Oil extracted from Rice Bran
(Hiroshima U. H.S.) *Azuma Yukari, *Miyasho Reina, *Yuuki Kyoko
Rice Bran
Biodiesel Fuel
Catalyst
13-i400
9:449:56E03Direct synthesis of dimethyl ether from CO2 hydrogenation over Cu-ZnO-ZrO2-Al2O3 catalysts prepared using the sol-gel method
(Shizuoka U.) *Kofuji Hiroto, Takeishi Kaoru
Dimethyl ether (DME)
Cu-ZnO-ZrO2-Al2O3 catalysts
CO2 hydrogenation
5-a350
9:5610:08E04Preferential oxidation of carbon monoxide over Cu-CeO2-Al2O3 catalysts prepared using the sol-gel method
(Shizuoka U.) *Ando Koki, Mochizuki Kaoru, Takeishi Kaoru
CO-PROX
Cu-CeO₂-Al₂O₃ catalysts
sol-gel method
5-a384
10:0810:20E05Study on Correlation between Chemical Composition and Photocatalytic Reactivity of Titanium Niobium Oxides.
(Shizuoka Inst. Sci. Tech.) *Iwata Emi, Tojo Tomohiro
Titanium Niobium Oxides
Photocatalytic Reaction
Chemical Composition
5-a105
10:2010:32E06Effect of graphene oxide addition on photocatalytic activity of g-C3N4/HNb3O8 nanosheet composite photocatalytic membranes
(Kobe.U.) *Moriguchi Kana, (Kobe U./MaF Tech Center) Nakagawa Keizo, (NTUST) Hu Chechia, (Kobe.U.) Tachikawa Takashi, (Kobe.U.MaF Tech Center) Okamoto Yasunao, (Kobe U./MaF Tech Center) Matuoka Atsushi, Kamio Eiji, Kitagawa Tooru, Yoshioka Tomohisa, Matsuyama Hideto
carbon nitride nanosheet
niobate nanosheet
graphene oxide
5-a187
10:3210:44E07The study of the photocatalysts reaction greatly accelerate with additive
(Nanyo Senior H.S.) *kawabata kenta, *tomioka yasunari
Photocatalyst
Environment
Cocatalyst
5-a33
(10:50–12:02) (Chair: Gabe Atsushi, Horie Takafumi)
10:5011:02E09The research for Rust Catalytic action of titanium dioxide
(Tsuyama H.S.) *Iizuna Otoha, *Kusaka Sara, *Nagao Mana, *Nishihara Kaho, *Yorimoto Shiori
Rust
Titanium dioxide
Photocatalytic action
5-a134
11:0211:14E10Difference in the amount of rust produced by metals
(Nirasaki H.S.) *Aiyoshi Yuto, *Hisasue Yuzuki, *Akiyama Rino, *Ochiai Rin
rust
aqueous solution
metal
5-i239
11:1411:26E11Development of new catalysts for low-temperature CO2 methanation
(Ibaraki U.) *Jinushizono T., Yamauchi N., Kobayashi Y., (Hokkaido U.) Tada S.
methanation
ruthenium
zirconia
5-a106
11:2611:38E12Synthesis of fatty alcohol from ethanol and methanol
(Tohoku U.) *Wake Shota, Hiromori Kousuke, Shibasaki-Kitakawa Naomi, Takahashi Atsushi
solid catalyst
fatty alcohol
active site
5-a321
11:3811:50E13Catalytic activity evaluation and structure optimization of visible light-sensitive CuOx/TiO2 photocatalysts using in-situ measurement technique
(U.Tokyo) *Tanaka Jun, Nakajima Yusuke, Shimogaki Yukihiro, Momose Takeshi
photocatalyst
visible light
structural optimization
5-a126
11:5012:02E14characteristics of solid catalysts that can generate ethylene and new solid catalysts
(Kozu H.S.) *Nakamura Kousin, *Sogi Yamato, Numazawa Sana, Haratani Hina, Miki Kasumi, Mizohata Reon
ethylene
solid catalyst
proton
5-a44
(13:00–14:12) (Chair: Nakagawa Keizo, Takeishi Kaoru)
13:0013:12E20Catalyst development for low-temperature methanol synthesis by CO2 hydrogenation
(Ibaraki U.) *Mukaiyama R., Yamauchi N., Kobayashi Y., (Hokkaido U.) Tada S.
CO2 hydrogenation
palladium
methanol
5-a119
13:1213:24E21Catalytic Transfer Hydrogenation of xylose to xylitol using light alcohols as hydrogen donors
(Kyoto U.) *Murakami Shuka, Hiraoka Taku, Fujitsuka Hiroyasu, Kawase Motoaki
catalytic transfer hydrogenation
carbon-supported catalyst
xylitol
5-a28
13:2413:36E22Investigation of oxidation treatment conditions for alumina-supported nickel oxide catalyst used for dehydrogenation of isobutane
(Tokushima U.) *Iwai T., Shimoda N., Sugiyama S., (Mitsubishi Chemical) Kato Y., Ninomiya W.
dehydrogenation
isobutane
nickel oxide
5-a32
13:3613:48E23Hydrothermal Synthesis of stibnite ˇÁHydrothermal Synthesis by Neutronss ˇÁ
(Saijo H.S.) *Sasaki Towa, *Kuwamura syou, *Hosokawa Yue, *Terada Ririko, *Fujimoto Yuzuki, *Nishimura Oriha, *Usami Takamasa, *Inami Hina, *Fujita Yui, *Itou Hitomi, *Watanabe Hinata
Stibnite
Hydrothermal Synthesis
Sodium Chloride
5-a295
13:4814:00E24Ammonia Methanation with ruthenium-based hybrid catalysts
(Hiroshima U.) *Imamura S., Sunamoto R., Miyaoka H., Ichikawa T., Saima H.
Carbon recycle
Ammonia
Methanation
5-a22
14:0014:12E25Visible light-driven hydrogen generation by organic polymer materials in the Ru(bpy)32+/Metylviologen/EDTA system
(NITTC) *Akiyama Z, *Koma R, Iwasaki S, Okuzaki S, Shiroishi H
hydrogen generation
organic polymer materials
Visible light-driven
5-a346
(14:20–15:44) (Chair: Sugiyama Shigeru, Fujitsuka Hiroyasu)
14:2014:32E27Liquid phase selective oxidation of glycerol using atmospheric pressure non-equilibrium plasma without catalyst
(Tohoku U.) *Nakagaki Yuya, Chida Tsutomu, Hiromori Kousuke, Shibasaki-Kitakawa Naomi, Sasaki Shota, Takahashi Atsushi
atmospheric pressure non-equilibrium plasma
reactive oxygen species
selective oxidation
5-c332
14:3214:44E28Development of cellulose hydrolysis catalysts by controlling amounts and types of acid sites on carbon
(NIT Kurume) *Chouno T., Gabe A.
hydrolysis of cellulose
oxygen containing functional groups
carbonization
5-g395
14:4414:56E29Development of zeolite-based catalysts for controlling hydroisomerization and cracking of long-chain n-paraffins for SAF production
(Tokyo Tech) *Tsuchiya T., Saika T., Kimura K., (Kyoto U./Tokyo Tech) Fujiysuka H., (Tokyo Tech) Tago T.
SAF
Zeolite
Platinium
5-a297
14:5615:08E30Low temperature CVD process development for AlN thin films
(U. Tokyo) *Obara S., Ninomiya T., Takagi T., Momose T., Shimogaki Y.
AlN film
chemical vapor deposition
low temperature
5-h175
15:0815:20E31CVD process for perovskite thin films from molten bismuth
(Kyoto U.) *Tanabe M., Yang Z., Kawase M.
CVD
perovskite solar cell
molten bismuth
5-h27
15:2015:32E32Solubilization of biomass components by hydrothermal decomposition of biomass with organic solvents
(Kansai U.) *Hamamoto Y., Hasegawa I., Hayashi J.
biomass
organosolv
hydrothermal decomposition
5-g168
15:3215:44E33Study on enhancement of gas-liquid mass transfer in Taylor Flow
(Osaka Metro. U.) *Ikeda Toshitake, Watabe Yoshihide, Horie Takafumi, Okita Erika, Yasuda Masahiro
Taylor Flow
mass transfer enhancement
spiral tube
5-f163
Hall F
(9:32–10:44) (Chair: Saima Hitoshi, Momose Takeshi)
9:329:44F02Intensification of aldol condensation process using a liquid-liquid slug flow reactor
(Osaka Metro. U.) *Yoshimura Taichi, Horie Takafumi, (Mitsubishi Chemical) Takahashi Makoto, (Osaka Metro. U.) Watabe Yoshihide, Okita Erika, Yasuda masahiro
slug flow
aldol condensation
mass transfer enhancement
5-f84
9:449:56F03Evaluation of mixing performance in a novel microchannel with oscillatory flow
(Osaka Metro. U.) *Hashimoto Yuki, Horie Takafumi, Murotani Ryosuke, Okita Erika, Yasuda Masahiro
Microreactor
Oscillatory flow
Mixing
5-f164
9:5610:08F04Control of the conditions of redox reaction of indigo carmine
(Ono H.S.) *Yamaguchi K., *Yamamoto H., *Yasunaga Y.
indigo carmine
redox
temperature
5-i282
10:0810:20F05Analysis of mass transfer resistance in PEFC cathode reaction based on reaction engineering modeling
(Kyoto U.) *Okada Y., Ogawa H., Kageyama M., Gyoten H., Kawase M.
polymer electrolyte fuel cell
oxygen reduction reaction
mass transfer resistance
5-a283
10:2010:32F06Evaluation of catalyst system using electricity for isopentane dehydrogenation
(Shizuoka U.) *Mino Kazuhide, Karasawa Fumiya, Akama Hiroshi, Watanabe Ryo, Fukuhara Choji
Dehydrogenation
Structured catalyst
Electric internal heating
5-a394
10:3210:44F07Accelerating effect of microwaves from mutarotation measurements
(U. Hyogo) *Hueki Takashi, Asakuma Yusuke
microwave
mutarotation
optical rotation
5-i315

Technical program
25th SCEJ Students Meeting (online, 2023)

© 2023 The Society of Chemical Engineers, Japan. All rights reserved.
Most recent update: 2023-03-16 14:37:10
For more information contact Organizing Committee, 25th SCEJ Students Meeting (online, 2023)
E-mail: inquiry-stu25www3.scej.org
This page was generated by easp 2.47; proghtml 2.42 (C)1999-2018 kawase