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Fuel cell technologies : state and perspectives
Fuel Cells have become a potentially highly efficient sustainable source of energy and electricity for an ever-demanding power hungry world. The two main types of fuel cells ripe for commercialisation are the high temperature solid oxide fuel cell (SOFC) and the low temperature polymer electrolyte m...
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| Auteurs principaux : | , , |
|---|---|
| Format : | Livre |
| Langue : | anglais |
| Titre complet : | Fuel cell technologies : state and perspectives / Nigel Sammes, Alevtina Smirnova and Oleksandr Vasylyev |
| Édition : | 1st ed. 2005. |
| Publié : |
Dordrecht :
Springer Netherlands
, [20..] Cham : Springer Nature |
| Collection : | NATO science series Series II Mathematics, physics, and chemistry ; 202 |
| Accès en ligne : |
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| Contenu : | Historic Aspects of Fuel Cell Development in Ukraine. Solid Oxide Fuel Cells in Russia. Intermediate-Temperature SOFC Electrolytes. Scandia-Zirconia Electrolytes and Electrodes for SOFCS. Exploration of Combustion CVD Method for YSZ Thin Film Electrolyte of Solid Oxide Fuel Cells. Development of DMFC for Portable Application. Synthesis of Porous and Dense Elements of SOFC by Electron Beam Physical Vapor Deposition (EBPVD). Fullerene Structures Suitable for Fuel Cells Electrodes. Metallic Materials in Solid Oxide Fuel Cells. SOFC Worldwide Technology Development Status and Early Applications. Recent Results of Stack Development at Forschungszentrum Jülich. Configuration of Twin Walls in LSGMO. Structural Stability and Ion Transport in LaSr2Fe1?yCryO8+?. Electric Power Generation Based on Coal Slurry Electrolysis with Subsequent Usage of Produced Hydrogen in Fuel Cells. Results of Organic Fuel Conversion at Fuel Cell Test Installation. CIP-Based Fabrication of SOFC Ceramic Components from Oxide Nanocrystalline Powder Materials. The State of Fuel Cells and its Development in Ukraine. Synthesis of Cermet Sr(Ti,Fe)O3-?-PtRu by Combustion. Hydrogen Storage in Metal Hydride Under Action of Sunlight. Hydrides of Transition Metals as Hydrogen Accumulators for Power Engineering. Mathematical Modeling and Experimental Study of Proton Exchange Membrane Fuel Cells. Experimental and Theoretical Study of Metal-Hydride Reactors. Cellulose-Precursor Synthesis of Electrocatalytically Active Components of SOFCs and Mixed-Conducting Membrane Reactors. Glass-Ceramic Sealants for SOFC-Based Systems. Effect of Uphill Diffusion in Solid Electrolytes ZrO2+8mol.%Sc2O3 and ZrO2 +8mol.% Y2O3. Nanoparticle Synthesis of LSM SOFC Cathode Materials. Perspective Materials for Application in Fuel-Cell Technologies. Electroconductivity of the Oxide Interlanthanoids with Perovskite Structure. Electroconductivity of the Bulk and Grain Boundaries in the 0.8CeO2-0.2Gd2O3 Electrolyte Prepared from Nanopowders. A Two Phase Model for Electrochemical Systems. Effect of Iron Oxide on Structure of Y-Stabilized Zirconia Ceramic. Structure, Thermal Expansion and Phase Transition in La0.92Sr0.08Ga0.92Ti0.08O3 Single Crystal. Investigation of Hydrogen Influence on Structure of Amorphous Alloys Mg-Cu-Y and Mg-Ni-Y by New Method of Diffraction from Atomic Coordinate Spheres. The YSZ Electrolyte Surface Layer: Existence, Properties, and Effect on Electrode Characteristics. Solid Electrolytes from Stabilized Zirconium Oxide that are Developed in O.J.S.C. Ukrainian Research Institute of Refractories Named After A.S. Berezhnoy. Nanocristalline Powders System ZrO2 Sc2O3 for Solid-State Combustion Cells. Structural Peculiarities and Properties of (La,Sr)(Mn,Me)O3 (Me=Cu,Cr). Simple Method for the Study of Transition Metal Valence State in Mixed-Valence Compounds. Perovskite Related Materials for Cathode Applications. Pure Hydrogen for Fuel Cells: A Novel Design of Compact Endothermic Catalytic Steam Reformer. Microstructural Characterization of La-Cr-O Thin Film Deposited by RF Magnetron Sputtering on the Stainless Steel Interconnect Materials for SOFC Application. CaTiO3-LaCrO3-CaCrO3 and CaTiO3-LaCrO3-La2/3TiO3 Quasi-Ternary Systems. SOFC Powder Synthesis by the Organic Steric Entrapment Method. Nanoscaled Oxide Thin Films for Energy Conversion |
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Fuel Cell Technologies: State and Perspectives |
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| 200 | 1 | |a Fuel cell technologies |e state and perspectives |f Nigel Sammes, Alevtina Smirnova and Oleksandr Vasylyev | |
| 205 | |a 1st ed. 2005. | ||
| 214 | 0 | |a Dordrecht |c Springer Netherlands | |
| 214 | 2 | |a Cham |c Springer Nature |d [20..] | |
| 225 | 0 | |a Nato Science Series II:, Mathematics, Physics and Chemistry |v 202 | |
| 320 | |a Bibliogr. en fin de chapitre. Index | ||
| 327 | 1 | |a Historic Aspects of Fuel Cell Development in Ukraine |a Solid Oxide Fuel Cells in Russia |a Intermediate-Temperature SOFC Electrolytes |a Scandia-Zirconia Electrolytes and Electrodes for SOFCS |a Exploration of Combustion CVD Method for YSZ Thin Film Electrolyte of Solid Oxide Fuel Cells |a Development of DMFC for Portable Application |a Synthesis of Porous and Dense Elements of SOFC by Electron Beam Physical Vapor Deposition (EBPVD) |a Fullerene Structures Suitable for Fuel Cells Electrodes |a Metallic Materials in Solid Oxide Fuel Cells |a SOFC Worldwide Technology Development Status and Early Applications |a Recent Results of Stack Development at Forschungszentrum Jülich |a Configuration of Twin Walls in LSGMO |a Structural Stability and Ion Transport in LaSr2Fe1?yCryO8+? |a Electric Power Generation Based on Coal Slurry Electrolysis with Subsequent Usage of Produced Hydrogen in Fuel Cells |a Results of Organic Fuel Conversion at Fuel Cell Test Installation |a CIP-Based Fabrication of SOFC Ceramic Components from Oxide Nanocrystalline Powder Materials |a The State of Fuel Cells and its Development in Ukraine |a Synthesis of Cermet Sr(Ti,Fe)O3-?-PtRu by Combustion |a Hydrogen Storage in Metal Hydride Under Action of Sunlight |a Hydrides of Transition Metals as Hydrogen Accumulators for Power Engineering |a Mathematical Modeling and Experimental Study of Proton Exchange Membrane Fuel Cells |a Experimental and Theoretical Study of Metal-Hydride Reactors |a Cellulose-Precursor Synthesis of Electrocatalytically Active Components of SOFCs and Mixed-Conducting Membrane Reactors |a Glass-Ceramic Sealants for SOFC-Based Systems |a Effect of Uphill Diffusion in Solid Electrolytes ZrO2+8mol.%Sc2O3 and ZrO2 +8mol.% Y2O3 |a Nanoparticle Synthesis of LSM SOFC Cathode Materials |a Perspective Materials for Application in Fuel-Cell Technologies |a Electroconductivity of the Oxide Interlanthanoids with Perovskite Structure |a Electroconductivity of the Bulk and Grain Boundaries in the 0.8CeO2-0.2Gd2O3 Electrolyte Prepared from Nanopowders |a A Two Phase Model for Electrochemical Systems |a Effect of Iron Oxide on Structure of Y-Stabilized Zirconia Ceramic |a Structure, Thermal Expansion and Phase Transition in La0.92Sr0.08Ga0.92Ti0.08O3 Single Crystal |a Investigation of Hydrogen Influence on Structure of Amorphous Alloys Mg-Cu-Y and Mg-Ni-Y by New Method of Diffraction from Atomic Coordinate Spheres |a The YSZ Electrolyte Surface Layer: Existence, Properties, and Effect on Electrode Characteristics |a Solid Electrolytes from Stabilized Zirconium Oxide that are Developed in O.J.S.C. Ukrainian Research Institute of Refractories Named After A.S. Berezhnoy |a Nanocristalline Powders System ZrO2 Sc2O3 for Solid-State Combustion Cells |a Structural Peculiarities and Properties of (La,Sr)(Mn,Me)O3 (Me=Cu,Cr) |a Simple Method for the Study of Transition Metal Valence State in Mixed-Valence Compounds |a Perovskite Related Materials for Cathode Applications |a Pure Hydrogen for Fuel Cells: A Novel Design of Compact Endothermic Catalytic Steam Reformer |a Microstructural Characterization of La-Cr-O Thin Film Deposited by RF Magnetron Sputtering on the Stainless Steel Interconnect Materials for SOFC Application |a CaTiO3-LaCrO3-CaCrO3 and CaTiO3-LaCrO3-La2/3TiO3 Quasi-Ternary Systems |a SOFC Powder Synthesis by the Organic Steric Entrapment Method |a Nanoscaled Oxide Thin Films for Energy Conversion | |
| 330 | |a Fuel Cells have become a potentially highly efficient sustainable source of energy and electricity for an ever-demanding power hungry world. The two main types of fuel cells ripe for commercialisation are the high temperature solid oxide fuel cell (SOFC) and the low temperature polymer electrolyte membrane fuel cell (PEM). The commercial uses of which include, but are not limited to, military, stand-by power, commercial and industrial, and remoter power. However, all aspects of the electricity market are being considered. This book has brought together a team of world-renowned experts in all aspects of fuel cell development for both SOFC and PEM in a workshop environment. The workshop held between June 6 10, 2004 was held in the capital city of the Ukraine, Kiev. The reason for the venue was that Ukraine is the third largest resource of zircon sands, a major source of material for the solid oxide fuel cell. Ukraine is looking at undertaking a very large effort in the solid oxide fuel cell arena, and hopes, one day, to be an international player in this market, and this book is an outcome from the workshop. The book focuses on the issues related to fuel cells, particularly the state-of-the-art internationally, the issues that were of particular interest for getting fuel cells fully commercialized, and advances in fuel cell materials and technology. The focus was on all types of fuel cells, but the emphasis was particularly on solid oxide fuel cells (SOFC), due to their importance to the host country. The book is an essential reference to researchers, academics and industrialists interested in up-to-date information on SOFC and PEM development | ||
| 371 | 0 | |a Accès en ligne pour les établissements français bénéficiaires des licences nationales | |
| 371 | 0 | |a Accès soumis à abonnement pour tout autre établissement | |
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