Time | Paper ID | Title / Autors | Keywords | Topic code | Ack. number |
---|---|---|---|---|---|
Hall J, Day 1 | |||||
(10:00–11:00) ( Kikuchi R., Tukui S.) | |||||
J104 | Controlling the Micro/Nano-structures of Metal Nanoparticles/porous Si for the Enhancement of Solar Cell Efficiencies | Metal nanoparticle Micro/nano structure Si solar cell | S-4 | 972 | |
J105 | Relationship between Crystallinity of Titanium Oxide and the Performance of P3HT/ICBA Organic Solar Cell | Titanium Oxide organic solar cell crystallinity | S-4 | 979 | |
J106 | Effect of Sb2S3 Microstructure on Photoelectric Conversion Efficiency of Sensitized Semiconductor Solar Cells | solar cell Sb2S3 heterojunciton | S-4 | 995 | |
(11:00–12:00) ( Tukui S., Kikuchi R.) | |||||
J107 | [Invited Lecture] Solar cell, Energy Management/Smart Grid, Mega Solar Power Plant | Solar Cell Smart Grid Mega Solar Power Plant | S-4 | 924 | |
(13:00–14:00) ( Tsujiguchi T., Tamaki T.) | |||||
J113 | Clarification on Coupling Phenomena in Single Cell of PEFC with In-plane Temperature Distribution Data Measured by Thermograph | PEFC In-plane Temperature Distribution Coupling Phenomena | S-4 | 214 | |
J114 | The effect of operating conditions on water transport situation in the membrane of polymer electrolyte fuel cell. | PEFC water transport NWTC | S-4 | 136 | |
J115 | Modeling of Heat Transfer in Single Cell of PEFC with Separator Temperature Data Obtained by Thermograph | PEFC Heat Transfer Model Temperature Distribution Analysis | S-4 | 211 | |
(14:00–15:00) ( Tamaki T., Tsujiguchi T.) | |||||
J116 | Relationship between microstructure of carbon electrode and effective electrical conductivity | PEFC Micro porous layer electrical conductivity | S-4 | 994 | |
J117 | Analysis of oxygen reduction reaction in the cathode catalyst layer of PEFC | PEFC oxygen reduction reaction kinetics | S-4 | 907 | |
J118 | Establishment of through-plane measurement of membrane conductivity in polymer electrolyte fuel cell | ion exchange membranes through-plane measurement conductivity | S-4 | 260 | |
(15:00–16:00) ( Kubota J., Fukunaga H.) | |||||
J119 | Development of PEFC cathode catalyst layer with core structure of carbon aggregate | PEFC catalyst layer ionomer | S-4 | 971 | |
J120 | PEFC electrocatalyst using FePt porous nanocapsules | PEFC FePt nanocapsules electrocatalyst | S-4 | 591 | |
J121 | Catalytic activity of carbon black-supported V-Mo oxide catalysts for oxygen reduction reaction | PEFC oxygen reduction reaction non-platinum catalysts | S-4 | 510 | |
(16:00–16:40) ( Fukunaga H., Ootomo J.) | |||||
J122 | The oxygen reduction reaction of well-dispersed TaOx nanoparticles on carbon black for PEFC applications. | PEFCs Oxygen reduction reaction tantalum oxide | S-4 | 515 | |
J123 | Activity of niobium-doped titanium oxide catalysts for oxygen reduction reaction of polymer electrolyte fuel cells | PEFC Oxygen reduction reaction niobium doped titanium oxide71 | S-4 | 938 | |
Hall J, Day 2 | |||||
(9:20–10:20) ( Inoue G., Koyama M.) | |||||
J202 | Evaluation of oxygen reduction activity and durability of silver-catalyzed gas diffusion electrode for zinc-air battery | Zinc-air battery Silver catalyst Oxygen reduction/evolution reaction | S-4 | 256 | |
J203 | Preparation of Li2FeP2O7/C and its lithium battery performance | Li2FeP2O7 Cathode Lithium batteries | S-4 | 374 | |
J204 | Mechanism of lithium-ion battery explosion | lithium-ion battery mechanism explosion | S-4 | 847 | |
(10:20–11:00) ( Koyama M.) | |||||
J205 | The Effect of Si Particle Morphology and Coating and Drying Process to the Si Anode Performance for Li-ion Batteries | Li-ion battery silicon anode drying process | S-4 | 957 | |
J206 | Development of anisotropy in porous collector by electrodeposition with hydrogen bubble template method | porous collector electrodeposition hydrogen bubble | S-4 | 983 | |
(11:00–12:00) ( Tukui S.) | |||||
J207 | [Invited Lecture] Development and future prospects of all-solid-state battery | all-solid-state battery | S-4 | 913 | |
(13:00–14:00) ( Ootomo J., Inoue G.) | |||||
J213 | Impact of various hydrogen production options on the reduction of GHG emissions | hydrogen production GHG emissions energy system modeling | S-4 | 919 | |
J214 | First-principles Study on Electronic Structure of Solid Oxide Fuel Cell Cathode | SOFC Cathode First-principles | S-4 | 937 | |
J215 | Conductivity changes in reductive atmosphere of materials with K2NiF4 structure (PrSrInO4) as electrolyte material for proton-type Solid Oxide Fuel Cells | Solid oxide fuel cell electrolyte ionic conductor | S-4 | 990 | |
(14:00–14:40) ( Fukunaga H.) | |||||
J216 | Evaluation of microstructure and proton conductivity in phosphate glass-ceramics | proton conducting glass-ceramics sol-gel method fuel cell | S-4 | 954 | |
J217 | Study on physicochemical properties for proton conductivity in lanthanum tungstate | proton conductor lanthanum tungstate fuel cell | S-4 | 986 | |
Hall J, Day 3 | |||||
(9:20–10:20) ( Tukui S., Nakagawa N.) | |||||
J302 | Effect of anode-additive PrBaInO4 and its derivative product on the electrochemical performance of solid oxide fuel cells | solid oxide fuel cell anode proton conductor | S-4 | 934 | |
J303 | Performance and durability of La0.85Sr0.15Cr1-xNixO3-CeO2 based oxide anode for SOFC | Solid oxide fuel cell oxide anode perovskite | S-4 | 940 | |
J304 | Contribution of Direct-Oxidation of Carbon in Rechargeable Direct Carbon Fuel Cell | solid oxide fuel cell direct carbon | S-4 | 949 | |
(10:20–11:00) ( Nakagawa N., Fukunaga H.) | |||||
J305 | Characterization of Gd0.5Sr0.5CoO3 cathode thin film for SOFC | SOFC GSCO Thin film | S-4 | 143 | |
J306 | Relationship between pulse jet interval and anode reaction in Pulse Jet-Rechargeable Direct Carbon Fuel Cell | SOFC direct carbon isooctane | S-4 | 963 | |
(11:00–12:00) ( Fukunaga H., Tukui S.) | |||||
J307 | [Invited Lecture] Development and future prospects of reversible solid oxide electrolysis cell (SOEC) / solid oxide fuel cell (SOFC) | Reversible SOFC/SOEC | S-4 | 888 | |
(13:00–14:00) ( Nishimura A., Kawase M.) | |||||
J313 | Study on a highly active catalyst layer using CNF catalyst | direct methanol fuel cell carbon nanofiber catalyst layer | S-4 | 289 | |
J314 | Electrode catalyst using TiO2 modified CNF support for alcohol oxidation | TiO2 modified CNF support Electrode catalyst Direct Alcohol Fuel Cell | S-4 | 291 | |
J315 | Synthesis of 3D carbon composite and evaluation of 3D carbon supported PtPd nanocrystal | graphene nanocrystal fuel cell | S-4 | 180 | |
(14:00–14:40) ( Kawase M., Nishimura A.) | |||||
J316 | Ethanol oxidation reaction by the Pt nanoparticles supported on TiO2 embedded carbon nanofiber | Ethanol oxidation reaction Pt nanoparticles TiO$2$ embedded carbon nanofibersupport | S-4 | 296 | |
J317 | Overpotential analysis of direct formic acid fuel cell | Direct Formic Acid Fuel Cell Overpootential Cell Structure | S-4 | 442 |