[EE] Catalysis in energy conversion and energy carriers | 10th Tokyo Conference on Advanced Catalytic Science and Technology (TOCAT 10)

Session Details

Poster PresentationGeneral session : Catalysis in energy conversion and energy carriers

[EE]Catalysis in energy conversion and energy carriers

Thu. Aug 20, 2026 6:30 PM - 8:00 PM JST
Thu. Aug 20, 2026 9:30 AM - 11:00 AM UTC

PS6(International Confference Hall)

[EE-01]Reaction-induced Core–shell Iron Catalysts Enable Ammonia Synthesis under Mild Conditions

*Yuan Jing¹, Jyuna Shimizu¹, Masashi Hattori¹, Satoshi Ishikawa¹, Takashi Toyao², Michikazu Hara¹ (1. Institute of Science Tokyo (Japan), 2. Hokkaido University (Japan))

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[EE-02] Cancel

[EE-03]Next-Generation Catalysts for Ammonia Synthesis: Mechanistic Insights and Energy Efficiency

Weronika Grzesik¹, *Izabela Czekaj^1,2 (1. Faculty of Chemical Engineering and Technology, Cracow University of Technology (Poland), 2. Interdisciplinary Center for Circular Economy, Cracow University of Technology (Poland))

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[EE-04]Alternating Surface Coverage of Reactive Intermediates over Low-temperature NH₃ Synthesis by Support Material design

*Yuma Miyazaki¹, Fuminao Kishimoto¹, Kazuki Shun², Kohsuke Mori², Kazuhiro Takanabe¹ (1. The University of Tokyo (Japan), 2. The University of Osaka (Japan))

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[EE-05]Validity of the Brønsted–Evans–Polanyi Relationship for Ammonia Synthesis over Mesoporous Carbon-Supported RuFe Alloy Catalysts

*Li-Yu Wang¹, Shih-Yuan Chen², Genki Horiguchi², Takehisa Mochizuki², Chia-Min Yang¹ (1. Natl. Tsing Hua Univ. (Taiwan), 2. AIST (Japan))

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[EE-06]Electrochemical System for Ammonia Synthesis from Water and Nitrogen with Ru Catalysts and Molten Hydroxide Electrolytes

*Sakura Ooyama¹, Raisei Sagara¹, Aika Hirata¹, Jun Kubota¹ (1. Fukuoka university (Japan))

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[EE-07]Development of BaZrO₃_-_xN_y as a Support of Ni Catalyst for Ammonia Decomposition

*Kazuki Miyashita¹, Masayoshi Miyazaki¹, Hideo Hosono¹, Masaaki Kitano¹ (1. Institute of Science Tokyo (Japan))

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[EE-08]Catalyst Design for Energy-efficient Ammonia Cracking Driven by Microwaves

*Sota Kuramoto¹, Fuminao Kishimoto¹, Kazuhiro Takanabe¹ (1. The University of Tokyo (Japan))

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[EE-09]Acceleration of Ammonia Decomposition on Co/CeO₂ Catalysts by Ba Addition via Electron Transfer through CeO₂

*Yuya Ashida¹, Taiga Yoshiike¹, Hideaki Ogino¹, Isao Nakamura², Tadahiro Fujitani² (1. Mitsubishi Gas Chemical Company Inc. (Japan), 2. National Institute of Advanced Industrial Science and Technology (AIST) (Japan))

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[EE-10]Efficient Ammonia Decomposition over Ce/NiO Single-Atom Catalysts

*Cheng Shiuan Li¹, Yu-Lun Lai¹, Chi-Hsuan Lin¹, Zi-Lan Liu¹ (1. Green Energy and Environment Research Laboratory, Industrial Technology Research Institute (Taiwan))

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[EE-11]Carbon-based Metal Catalyst Precursors for Efficient Ammonia Cracking.

*EMILE DARRON MAGGOTT¹, Nicola Scotti¹, Filippo Bossola¹, Vladimiro Dal Santo¹ (1. Consiglio Nazionale delle Ricerche - SCITEC (Italy))

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[EE-12]Design of Cost-effective Ru-free Perovskite Derived Catalysts with Optimized Ni Exsolution and Electronic Properties for High Performance Ammonia Decomposition

*Seungbeom Yoon¹, Jae Min Park¹, Do Heui Kim¹ (1. Seoul National University (Korea))

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[EE-13]Mechanism Elucidation of Ammonia Decomposition Reaction Assisted by an Electric Field

*Cheolung Lee¹, Yasushi Sekine², Jeong Gil Seo¹ (1. Hanyang Univ. (Korea), 2. Waseda Univ. (Japan))

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[EE-14]Designing Ni-Based Catalysts for Low-Temperature Ammonia Decomposition

*M.A. Shadab Siddiqui¹, Fahad Alam^1,3, M. Nasiruzzaman Shaikh^1,2 (1. King Fahd University of Petroleum and Minerals (Saudi Arabia), 2. Interdisciplinary Research Center for Hydrogen Technologies and Carbon Management (IRC-HTCM) (Saudi Arabia), 3. Interdisciplinary Research Center for Biosystems and Machines (Saudi Arabia))

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[EE-15]Membrane Reactor Assembled with Flat-Plate Hydrogen-Permeable Membrane and Ammonia Decomposition Catalyst for Producing Hydrogen from Ammonia

*Kaori Omata¹, Hideo Yoshinaga², Tomonori Nambu³ (1. University of Yamanashi (Japan), 2. TAIYO KOKO Co., Ltd. (Japan), 3. National Institute of Technology, Suzuka College (Japan))

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[EE-16]AMAZE: Integrated Technologies for Green Ammonia Synthesis and Catalytic Cracking as a Zero-Carbon Hydrogen Carrier

*Filippo Buttignol¹, Alberto Garbujo¹, Pierdomenico Biasi¹ (1. Research & Development Division, Casale SA (Switzerland))

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[EE-17]Engineering Egg-Shell Ru/K/Al₂O₃ Pellet Catalysts for Practical Ammonia Decomposition

*Dongun Kim¹, Tae Wan Kim¹, Young-Woong Suh¹ (1. Department of Chemical Engineering, Hanyang University (Korea))

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[EE-18]Ammonia Oxidation on Perovskites for Ammonia SOFCs

*Marcin Krzysztof Makosa-Szczygiel¹, Giuseppe Cicellin¹, David Waller², Magnus Rønning¹, De Chen¹ (1. Norwegian University of Science and Technology (Norway), 2. Yara Technology Center (Norway))

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[EE-19]Ni-Containing Catalysts Based on CeO₂-La₂O₃-Pr₆O₁₁ Solid Solutions for Dry Reforming of Methane

Olga Vodyankina¹, Pavel Putanenko¹, Natalia Dorofeeva¹, *Leonarda Francesca Liotta² (1. National Research Tomsk State University (Russia), 2. Institute for the Study of Nanostructured Materials (ISMN), National Research Council (CNR), Palermo, Italy (Italy))

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[EE-20]Microwave-enhanced Catalytic Pyrolysis of Polypropylene Waste via Fe-based Catalysts for CO-rich Syngas generation

*Ibrahim Maamoun^1,2, Rie Honda², Shuntaro Tsubaki^1,2,3, Noriyuki Igura^1,2, Andrew Chapman³, Satoshi Fujii⁴ (1. Graduate School of Bioresource and Bioenvironmental Sciences, Kyushu University. (Japan), 2. Department of Bioscience and Biotechnology, Faculty of Agriculture, Kyushu University. (Japan), 3. International Institute for Carbon Neutral Energy Research (I²CNER), Kyushu University. (Japan), 4. Department of Information and Communication System Engineering, National Institute of Technology, Okinawa College. (Japan))

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[EE-21]Novel Steam Reforming Catalyst for Biogenic Hydrogen Production: Evidence of Complete Real Tar Conversion in Updraft Gasification

*Manfred Nacken¹, Nadia Cerone², Francesco Zimbardi², Luca Contuzzi², Umberto Calice³, Tijana Pecirep¹, Carmine Florio², Gioseppe Zito², Giovanni Santilli² (1. C&CS catalysts and chemical specialties GmbH (Germany), 2. ENEA, Dipartimento Tecnologie Energetiche e Fonti Rinnovabili (Italy), 3. Università degli Studi della Basilicata (Italy))

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[EE-22]Activation, Methane Cracking Ability, and Deactivation of Iron–Aluminum Composite Catalysts for Production of Turquoise Hydrogen and Fibrous Carbon: From Acquiring Mechanistic Insights to Improving Catalyst Lifetime

*Shih-Yuan Chen¹ (1. National Institute of Advanced Industrial Science and Technology (AIST) (Japan))

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[EE-23]Investigation of Activity, Selectivity, and Stability of Industrial Fixed-Bed Cobalt Catalysts for Fischer-Tropsch Synthesis of Synthetic Aviation Fuel

*Judith Helena Mettke¹, Denzil Moodley², Jacobus Visagie², Marco Frank³, Erik Reichelt¹ (1. Fraunhofer IKTS (Germany), 2. Sasol SA (South Africa), 3. Sasol NL (Netherlands))

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[EE-24]Hydrogen Production by using Hybrid Sulfur System

*Taichi Tomizuka¹, Tokuto Tatsujima¹, Tetsuya Yamaki², Shin-ichi Sawada², Hiroshi Koshikawa², Kimio Yoshimura², Mikihiro Nomura¹ (1. Shibaura Institute of Technology (Japan), 2. Takasaki Institute for Advanced Quantum Science (Japan))

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[EE-25]CO₂ direct FT Synthesis over Cobalt Catalyst Supported on Rare Earth Oxide

*Atsushi Omori¹, Hayato Yoshida¹, Aoha Uchida¹, Kimiki Goto¹, Keigo Tashiro², Hong Ye¹, Shigeo Satokawa¹ (1. Seikei University (Japan), 2. Shizuoka University (Japan))

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[EE-26]Novel External-Hydrogen Free CO₂ Thermal Catalytic Conversion to Clean Fuels and Chemicals

*Piyasan Praserthdam¹ (1. Center of Excellence on Catalysis and Catalytic Reaction Engineering (Thailand))

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[EE-27]Development of Functional Materials using LiBr doped V₂O₅ for Coin Cell Battery Application

*Kaviyarasu Kasinathan¹ (1. University of South Africa (South Africa))

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[EE-28]Defective Ceria Nanorods Catalysts for Catalytic Cathode Materials in Lithium Carbon Dioxide Batteries

*Wei-Fan Kuan¹, Minh-Son Hoang¹, Ke-Chieh Lin¹ (1. Chang Gung University (Taiwan))

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[EE-29]Perovskite Catalyst for the Leaching Metals for Oxidative Dehydrogenation of Propane

*Zhao Yuan Xiao¹, Andrew C. Chien¹ (1. Feng Chia University (Taiwan))

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[EE-30]Development of Highly Durable Catalysts with Pyridyl-Pyrazole Ligands for Formic Acid Dehydrogenation

*Haruto Kuga¹, Yuichiro Himeda², Takuji Hirose^1,2, Koichi Kodama¹ (1. Graduate school of science and engineering, saitama university (Japan), 2. National institute of advanced industrial science and technology (Japan))

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[EE-31]Effect of Catalyst Pore Size on the Deoxygenation of Oleic Acid to Renewable Fuels over NiO/SiO₂ Catalysts

*Pawnprapa Pitakjakpipop¹, Praphavis Boonchuer², Harit Pitakjakpipop³, Wipark Anutrasakda² (1. National Energy Technology Center (ENTEC), National Science and Technology Development Agency (NSTDA) (Thailand), 2. Department of Chemistry, Faculty of Science, Chulalongkorn University (Thailand), 3. National Nanotechnology Center (NANOTEC), National Science and Technology Development Agency (NSTDA) (Thailand))

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[EE-32]Influence of Sulfidation Degree on the Performance of NiMo/Al₂O₃ Catalyst in Waste Tire Pyrolysis oil Hydrotreatment

*Huy Xuan Le¹, Tung Manh Nguyen¹, Olov Öhrman², Derek Creaser¹, Louise Olsson¹ (1. Chemical Engineering Division, Competence Centre for Catalysis, Chalmers University of Technology, Gothenburg 412 96, Sweden (Sweden), 2. Preem AB, Gothenburg SE-418 23, Sweden (Sweden))

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[EE-33]Comparative Study on the Influence of Dewatering of Pyrolysis Oil: Properties and Hydrodeoxygenation Upgrading

*Elham Nejadmoghadam¹, Olov Öhrman², Derek Creaser¹, Louise Olsson¹ (1. Chalmers university of technology (Sweden), 2. Preem AB (Sweden))

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[EE-34]In situ XAS for Mapping Iron Oxide Phases in Laminar Iron Dust Flames for Chemical Looping Process

*Lukas Braun^1,2, Fabian Hagen³, Dimosthenis Trimis³, Dmitry Doronkin^1,2, Jan-Dierk Grunwaldt^1,2 (1. Karlsruhe Inst. of Technol. (KIT), Inst. of Chem. Technol. and Poly. Chem.(ITCP) (Germany), 2. Karlsruhe Inst. of Technol. (KIT), Inst. of Catal. Res. and Technol. (IKFT) (Germany), 3. Karlsruhe Inst. of Technol. (KIT), Engler-Bunte-Inst., Combustion Technol. (EBI-VBT) (Germany))

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[EE-35]Nitrogen-doped Ordered Mesoporous Carbon with Improved Oxidation Stability and Catalytic Activity

*Mohamed R Berber^1,2, Hiroko Yamazaki¹, Makoto Uchida¹, Akihiro Iiyama¹, Yasuto Hoshikawa⁴, Toshihiro Miyao^2,3 (1. Hydrogen Fuel Cell Nanomaterials Center, University of Yamanashi (Japan), 2. Zero Emission MIRAI Research Center, University of Yamanashi (Japan), 3. Clean Energy Research Center, University of Yamanashi (Japan), 4. Fuji Research Laboratory, R & D Strategy Division, Tokai Carbon Co., Ltd. (Japan))

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