| 1 - 9 |
Network integration of distributed power generation
Dondi P, Bayoumi D, Haederli C, Julian D, Suter M |
| 10 - 15 |
Novel SOFC anodes for the direct electrochemical oxidation of hydrocarbon
Gorte RJ, Kim H, Vohs JM |
| 16 - 20 |
Development of a PEM fuel cell powered portable field generator for the dismounted soldier
Moore JM, Lakeman JB, Mepsted GO |
| 21 - 30 |
Compact mixed-reactant fuel cells
Priestnall MA, Kotzeva VP, Fish DJ, Nilsson EM |
| 31 - 34 |
Fuel cells for portable applications
Dyer CK |
| 35 - 41 |
Fuel processors for fuel cell vehicles
zur Megede D |
| 42 - 50 |
Functionally graded composite cathodes for solid oxide fuel cells
Hart NT, Brandon NP, Day MJ, Lapena-Rey N |
| 51 - 59 |
Feasibility study of the co-generation system with direct internal reforming-molten carbonate fuel cell (DIR-MCFC) for residential use
Sugiura K, Naruse I |
| 60 - 67 |
The development of effective heat and power use technology for residential in a PEFC co-generation system
Inaka H, Sumi S, Nishizaki K, Tabata T, Kataoka A, Shinkai H |
| 68 - 75 |
Development of a 50 kW PAFC power generation system
Yang JC, Park YS, Seo SH, Lee HJ, Noh JS |
| 76 - 82 |
Networked solid oxide fuel cell stacks combined with a gas turbine cycle
Selimovic A, Palsson J |
| 83 - 92 |
Design of stationary PEFC system configurations to meet heat and power demands
Wallmark C, Alvfors P |
| 93 - 101 |
Wood-fired fuel cells in an isolated community
McIlveen-Wright D, Guiney DJ |
| XI - XI |
Proceedings of the Seventh Grove Fuel Cell Symposium - Queen Elizabeth II Conference Centre, London, UK 11-13 September 2001 - Editorial
Moseley P |
| 102 - 108 |
Study of fuel cell co-generation systems applied to a dairy industry
Leal EM, Silveira JL |
| 109 - 115 |
Microwave synthesis of catalyst spinel MnCo2O4 for alkaline fuel cell
Nissinen T, Valo T, Gasik M, Rantanen J, Lampinen M |
| 116 - 121 |
Oxygen exchange measurements on perovskites as cathode materials for solid oxide fuel cells
Preis W, Bucher E, Sitte W |
| 122 - 125 |
New results of PEFC electrodes produced by the DLR dry preparation technique
Gulzow E, Kaz T |
| 126 - 135 |
Investigation of the degradation of different nickel anode types for alkaline fuel cells (AFCs)
Gulzow E, Schulze M, Steinhilber G |
| 136 - 141 |
Sintering behavior of Ln-doped ceria compounds containing gallia
Yoshida H, Miura K, Fukui T, Ohara S, Inagaki T |
| 142 - 145 |
Performance of intermediate temperature solid oxide fuel cells with La(Sr)Ga(Mg)O-3 electrolyte film
Fukui T, Ohara S, Murata K, Yoshida H, Miura K, Inagaki T |
| 146 - 152 |
Effect of the catalytic ink preparation method on the performance of polymer electrolyte membrane fuel cells
Shin SJ, Lee JK, Ha HY, Hong SA, Chun HS, Oh IH |
| 153 - 159 |
Performance of LiCoO2-coated NiO cathode under pressurized conditions
Han J, Kim SG, Yoon SP, Nam SW, Lim TH, Oh IH, Hong SA, Lim HC |
| 160 - 166 |
Performance of anode-supported solid oxide fuel cell with La0.85Sr0.15MnO3 cathode modified by sol-gel coating technique
Yoon SP, Han J, Nam SW, Lim TH, Oh IH, Hong SA, Yoo YS, Lim HC |
| 167 - 172 |
Effect of silicon carbide particle size in the electrolyte matrix on the performance of a phosphoric acid fuel cell
Song RH, Dheenadayalan S, Shin DR |
| 173 - 177 |
Performance evaluation of a Nafion/silicon oxide hybrid membrane for direct methanol fuel cell
Jung DH, Cho SY, Peck DH, Shin DR, Kim JS |
| 178 - 188 |
Ni-YSZ cermet anodes prepared by citrate/nitrate combustion synthesis
Marinsek M, Zupan K, Maeek J |
| 189 - 195 |
Endurance test on a single cell of a novel cathode material for MCFC
Soler J, Gonzalez T, Escudero MJ, Rodrigo T, Daza L |
| 196 - 205 |
Influence of lanthanum oxide as quality promoter on cathodes for MCFC
Escudero MJ, Novoa XR, Rodrigo T, Daza L |
| 206 - 214 |
Development and performance characterisation of new electrocatalysts for PEMFC
Escudero MJ, Hontanon E, Schwartz S, Boutonnet M, Daza L |
| 215 - 223 |
Modification of polymer electrolyte membranes for DMFCs using Pd films formed by sputtering
Yoon SR, Hwang GH, Cho WI, Oh IH, Hong SA, Ha HY |
| 224 - 230 |
Imaging of oxygen transport at SOFC cathode/electrolyte interfaces by a novel technique
Horita T, Yamaji K, Sakai N, Xiong XP, Kato T, Yokokawa H, Kawada T |
| 231 - 237 |
Small-scale testing of a precious metal catalyst in the autothermal reforming of various hydrocarbon feeds
Palm C, Cremer P, Peters R, Stolten D |
| 238 - 244 |
Internal reforming of methane in solid oxide fuel cell systems
Peters R, Dahl R, Kluttgen U, Palm C, Stolten D |
| 245 - 248 |
High-power direct ethylene glycol fuel cell (DEGFC) based on nanoporous proton-conducting membrane (NP-PCM)
Peled E, Livshits V, Duvdevani T |
| 249 - 257 |
Steam reforming of methanol over a Cu/ZnO/Al2O3 catalyst: a kinetic analysis and strategies for suppression of CO formation
Agrell J, Birgersson H, Boutonnet M |
| 258 - 263 |
Reactions of hydrocarbons in small tubular SOFCs
Saunders GJ, Kendall K |
| 264 - 273 |
Steam reforming of methanol over copper-based monoliths: the effects of zirconia doping
Lindstrom B, Pettersson LJ |
| 274 - 283 |
Incorporation of voltage degradation into a generalised steady state electrochemical model for a PEM fuel cell
Fowler MW, Mann RF, Amphlett JC, Peppley BA, Roberge PR |
| 284 - 294 |
Three-dimensional computational analysis of transport phenomena in a PEM fuel cell
Berning T, Lu DM, Djilali N |
| 295 - 303 |
Performance and lifetime analysis of the kW-class PEMFC stack
Ahn SY, Shin SJ, Ha HY, Hong SA, Lee YC, Lim TW, Oh IH |
| 304 - 312 |
Measurement of current distribution in a free-breathing PEMFC
Noponen M, Mennola T, Mikkola M, Hottinen T, Lund P |
| 313 - 322 |
Development of a compact 500 W class direct methanol fuel cell stack
Dohle H, Schmitz H, Bewer T, Mergel J, Stolten D |
| 323 - 327 |
Effects of dilution on methane entering an SOFC anode
Kendall K, Finnerty CM, Saunders G, Chung JT |
| 328 - 332 |
A novel preparation method for a self-humidifying polymer electrolyte membrane
Yang TH, Yoon YG, Kim CS, Kwak SH, Yoon KH |
| 333 - 337 |
Operational experience with the fuel processing system for fuel cell drives
Emonts B, Hansen JB, Grube T, Hohlein B, Peters R, Schmidt H, Stolten D, Tschauder A |
| 338 - 343 |
Design studies of mobile applications with SOFC-heat engine modules
Winkler W, Lorenz H |
| 344 - 352 |
Impact of the European Union vehicle waste directive on end-of-life options for polymer electrolyte fuel cells
Handley C, Brandon NP, van der Vorst R |
| 353 - 363 |
Options for refuelling hydrogen fuel cell vehicles in Italy
Mercuri R, Bauen A, Hart D |
| 364 - 369 |
Influence of electrode structure on the performance of a direct methanol fuel cell
Wei ZB, Wang SL, Yi BL, Liu JG, Chen LK, Zhou WJ, Li WZ, Xin Q |
| 370 - 376 |
Fuel cell power source for a cold region
Datta BK, Velayutham G, Goud AP |
| 377 - 380 |
Progress with the development of a CO2 capturing solid oxide fuel cell
Haines MR, Heidug WK, Li KJ, Moore JB |
| 381 - 383 |
Fuel cell systems for submarines: from the first idea to serial production
Psoma A, Sattler G |
| 384 - 387 |
Design and realization of a 300 W fuel cell generator on an electric bicycle
Cardinali L, Santomassimo S, Stefanoni M |
| 388 - 396 |
Design options for achieving a rapidly variable heat-to-power ratio in a combined heat and power (CHP) fuel cell system (FCS)
Colella W |
| 397 - 404 |
Implications of electricity liberalization for combined heat and power (CHP) fuel cell systems (FCSs): a case study of the United Kingdom
Colella W |
