Fuel Cells CompendiumDr. Nigel N.P Brandon, Dr. David Thompsett Elsevier, 24 nov 2005 - 632 pagine Fuel cells continue to be heralded as the energy source of the future, and every year an immense amount of research time and money is devoted making them more economically and technically viable. Fuel Cells Compendium brings together an up-to-date review of the literature and commentary surrounding fuel cells research. Covering all relevant disciplines from science to engineering to policy, it is an exceptional resource for anyone with an invested interest in the field.
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Pagina 3
... performance of these cells is illustrated in Fig. 2. These cells perform satisfactorily for extended periods of time under a variety of operating conditions with less than 0.1% per 1000h performance degradation [3]. The tubular SOFCs ...
... performance of these cells is illustrated in Fig. 2. These cells perform satisfactorily for extended periods of time under a variety of operating conditions with less than 0.1% per 1000h performance degradation [3]. The tubular SOFCs ...
Pagina 15
... performance improvements would be mapped. From the early 1930s, Francis T. Bacon researched fuel cells predominantly for their potential as energy storage devices [35]. It was not until August of 2000 [36] that a National Power ...
... performance improvements would be mapped. From the early 1930s, Francis T. Bacon researched fuel cells predominantly for their potential as energy storage devices [35]. It was not until August of 2000 [36] that a National Power ...
Pagina 16
... performance and the related parameter, power density, that is, kilowatts per kilogram and kilowatts per liter for the PEMFC stack. In this endeavor, the elevation of stack operating temperature, control of water management issues ...
... performance and the related parameter, power density, that is, kilowatts per kilogram and kilowatts per liter for the PEMFC stack. In this endeavor, the elevation of stack operating temperature, control of water management issues ...
Pagina 17
... performance was demonstrated at a current density of 5000A/ft2 at 0.5V. This performance was maintained for greater than 2000h at 500A/ft2 [57]. Further effort involved reductions in the quantities of electrocatalyst used in the ...
... performance was demonstrated at a current density of 5000A/ft2 at 0.5V. This performance was maintained for greater than 2000h at 500A/ft2 [57]. Further effort involved reductions in the quantities of electrocatalyst used in the ...
Pagina 21
... performance enhancement and cost reduction; all major noble metal catalyst producers, such as Johnson Matthey [92], Degussa Metals Catalyst Cerdec (dmc2) [93], Tanaka Kikinzoku Kogyo (TKK) [94] and Engelhard [95], have some activity in ...
... performance enhancement and cost reduction; all major noble metal catalyst producers, such as Johnson Matthey [92], Degussa Metals Catalyst Cerdec (dmc2) [93], Tanaka Kikinzoku Kogyo (TKK) [94] and Engelhard [95], have some activity in ...
Sommario
29 | |
53 | |
91 | |
107 | |
7 An assessment of alkaline fuel cell technology | 117 |
8 Molten carbonate fuel cells | 147 |
fundamentals and applications | 155 |
status of technologies and potential applications | 167 |
18 Advanced materials for improved PEMFC performance and life | 411 |
19 Polymerceramic composite protonic conductors | 425 |
20 Recent developments in hightemperature proton conducting polymer electrolyte membranes | 433 |
21 PEM fuel cell electrodes | 443 |
22 Review and analysis of PEM fuel cell design and manufacturing | 469 |
23 Aging mechanisms and lifetime of PEFC and DMFC | 503 |
24 Materials for hydrogen storage | 517 |
25 Fuel economy of hydrogen fuel cell vehicles | 531 |
a brief review | 189 |
12 A review on the status of anode materials for solid oxide fuel cells | 215 |
13 Advances aging mechanisms and lifetime in solidoxide fuel cells | 235 |
14 Components manufacturing for solid oxide fuel cells | 249 |
15 Engineered cathodes for high performance SOFCs | 261 |
16 Surface science studies of model fuel cell electrocatalysts | 275 |
17 Protonconducting polymer electrolyte membranes based on hydrocarbon polymers | 375 |
the need for high temperature polymers as a consequence of PEMFC water and heat management | 545 |
27 Portable and military fuel cells | 555 |
28 Microfabricated fuel cells | 561 |
29 Electrocatalytic membrane reactors and the development of bipolar membrane technology | 573 |
30 Compact mixedreactant fuel cells | 593 |
Subject Index | 607 |
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Parole e frasi comuni
achieved acid activity addition adsorbed adsorption anode applications atoms bond carbon catalyst catalyst layer cathode Chem chemical COad compared complexes components composite concentration conductivity conventional cost current density decrease dependence deposition diffusion direct effect efficiency electrical Electrochem electrode electrolyte energy fabrication formation fuel cell glucose groups heat higher hydrocarbon hydrogen improved increased International ionic layer liquid loading lower materials measurements mechanism membrane metal methanol method Nafion observed operating oxidation oxygen partial PEMFC performance phase plate platinum polymer polymer electrolyte potential prepared present pressure Proceedings production proton range reaction recent reduced reforming relative reported resistance selectivity shown shows SOFC Solid solution specific stability stack steam structure sulfonated supported surface Table temperature thermal transport
Brani popolari
Pagina 269 - Laboratory is operated by Battelle Memorial Institute for the US Department of Energy under Contract DE-AC06-76-RLO 1830.
Pagina 572 - The views and conclusions contained herein are those of the authors and should not be interpreted as necessarily representing the official policies or endorsements, either...
Pagina xiii - University of Victoria PO Box 3055, STN CSC. Victoria BC, Canada, V8W 3P6 Email: {wli, agullive, h/.hang}@ece.uvic.ca Abstract Recently, pulse position amplitude modulation IPPAM) has been proposed for Ultra-Wideband (UWB) communication systems.
Pagina 52 - GA Somorjai, Introduction to Surface Chemistry and Catalysis, Wiley, New York.
Pagina 24 - Second International Symposium on New Materials for Fuel Cell and Modern Battery Systems II, O.
Pagina 373 - JO'M. Bockris and BE Conway (Eds.) Modern Aspects of Electrochemistry, Plenum Press, New York, Volurae 10, 1975, p.
Pagina 186 - In: JO'M. Bockris, BE Conway, RE White (Eds.), Modern Aspects of Electrochemistry, Vol.
Pagina 369 - Ross, in: A. Wieckowski (Ed.), Interfacial Electrochemistry. Theory, Experiment and Applications. Marcel Dekker, New York, 1999, pp.
Pagina 212 - PN Dyer, RE Richards, SL Russek and DM Taylor, Solid State Ionics 134 (2000) 21.
Pagina 65 - In principle, a fuel cell operates like a battery. Unlike a battery, a fuel cell does not run down or require recharging. It will produce energy in the form of electricity and heat as long as fuel is supplied.