| 1 - 1 |
Proceedings of the Sixth Grove Fuel Cell Symposium Fuel Cells -The Competitive Option for Sustainable Energy Supply - 13-16 September, 1999, Queen Elizabeth II Conference Centre, London, UK
Lovering DG |
| 2 - 8 |
Challenges of implementing new technologies for sustainable energy opening address at the Sixth Grove Fuel Cell Symposium, London, 13-16 September 1999
Koch HJ |
| 9 - 15 |
Grove Medal acceptance address
Baker BS |
| 16 - 22 |
Applying fuel cell experience to sustainable power products
King JM, O'Day MJ |
| 23 - 27 |
Sustainable energy conversion: fuel cells - the competitive option?
Hart D |
| 28 - 33 |
Financial considerations of exploiting fuel cell technology
MacKerron G |
| 34 - 39 |
Challenges for fuel cells as stationary power resource in the evolving energy enterprise
Rastler D |
| 40 - 51 |
Challenges for fuel cells in transport applications
Chalk SG, Miller JF, Wagner FW |
| 52 - 56 |
The European Union approach to fuel cell development
Borthwick WKD |
| 57 - 60 |
The California fuel cell partnership: an avenue to clean air
Lloyd AC |
| 61 - 67 |
Fuel cells going on-board
Sattler G |
| 68 - 73 |
Planar solid oxide fuel cells: the Australian experience and outlook
Godfrey B, Foger K, Gillespie R, Bolden R, Badwal SPS |
| 74 - 83 |
The role of fuel cells in energy storage
Smith W |
| 84 - 89 |
Liberalisation - challenges and opportunities for fuel cells
Baentsch F |
| 90 - 97 |
Innovative concepts for the coproduction of electricity and syngas with solid oxide fuel cells
Vollmar HE, Maier CU, Nolscher C, Merklein T, Poppinger M |
| 98 - 110 |
Small-scale fuel cells for residential applications
Sammes NM, Boersma R |
| 111 - 116 |
Recent advances in direct methanol fuel cells at Los Alamos National Laboratory
Ren XM, Zelenay P, Thomas S, Davey J, Gottesfeld S |
| 117 - 121 |
An analysis of endurance issues for MCFC
Huijsmans JPP, Kraaij GJ, Makkus RC, Rietveld G, Sitters EF, Reijers HTJ |
| 122 - 129 |
SOFC technology development at Rolls-Royce
Gardner FJ, Day MJ, Brandon NP, Pashley MN, Cassidy M |
| 130 - 133 |
Fuel cell drives for road vehicles
Charnah RM |
| 134 - 139 |
Status of tubular SOFC field unit demonstrations
George RA |
| 140 - 144 |
The first demonstration of the 250-kW polymer electrolyte fuel cell for stationary application (Berlin)
Pokojski M |
| 145 - 150 |
Start-up, testing and operation of 1000 kW class MCFC power plant
Ishikawa T, Yasue H |
| 151 - 157 |
The prospects - fuel cell motorcycle in Taiwan
Wang JH, Chiang WL, Shu JPH |
| 158 - 161 |
The TES project - A joint initiative for an additional fuel infrastructure
Heuer W |
| 162 - 165 |
Alkaline fuel cells applications
Kordesch K, Hacker V, Gsellmann J, Cifrain M, Faleschini G, Enzinger P, Fankhauser R, Ortner M, Muhr M, Aronson RR |
| 166 - 172 |
Portable PEFC generator with propane as fuel
Ledjeff-Hey K, Kalk T, Mahlendorf F, Niemzig O, Trautmann A, Roes J |
| 173 - 180 |
Development and application of a generalised steady-state electrochemical model for a PEM fuel cell
Mann RF, Amphlett JC, Hooper MAI, Jensen HM, Peppley BA, Roberge PR |
| 181 - 196 |
Modelling of polymer electrolyte membrane fuel cells with variable degrees of water flooding
Baschuk JJ, Li XH |
| 197 - 201 |
Water transport in polymer membranes for PEMFC
Choi KH, Peck DH, Kim CS, Shin DR, Lee TH |
| 202 - 213 |
Conceptual design and modeling of a fuel cell scooter for urban Asia
Lin B |
| 214 - 222 |
A compact CO selective oxidation reactor for solid polymer fuel cell powered vehicle application
Dudfield CD, Chen R, Adcock PL |
| 223 - 227 |
Purifier-integrated methanol reformer for fuel cell vehicles
Jan H, Kim IS, Choi HS |
| 228 - 236 |
Fuel cell drive system with hydrogen generation in test
Emonts B, Hansen JB, Schmidt H, Grube T, Hohlein B, Peters R, Tschauder A |
| 237 - 242 |
Stainless steel as a bipolar plate material for solid polymer fuel cells
Davies DP, Adcock PL, Turpin M, Rowen SJ |
| 243 - 249 |
Critical assessment of power trains with fuel-cell systems and different fuels
Hohlein B, von Andrian S, Grube T, Menzer R |
| 250 - 254 |
Diffusion layer parameters influencing optimal fuel cell performance
Jordan LR, Shukla AK, Behrsing T, Avery NR, Muddle BC, Forsyth M |
| 255 - 260 |
Market prospects, design features, anal performance of a fuel cell-powered scooter
Colella WG |
| 261 - 268 |
The impinging jet flow cell - a novel method for the study of PEM fuel cell material
Koponen U, Peltonen T, Bergelin M, Mennola T, Valkiainen M, Kaskimies J, Wasberg M |
| 269 - 273 |
Development of a high-performance PEFC module operated by reformed gas
Isono T, Suzuki S, Kaneko M, Akiyama Y, Miyake Y, Yonezu I |
| 274 - 282 |
Use of stainless steel for cost competitive bipolar plates in the SPFC
Makkus RC, Janssen AHH, de Bruijn FA, Mallant RKAM |
| 283 - 288 |
Test results for fuel cell operation on anaerobic digester gas
Spiegel RJ, Preston JL |
| 289 - 293 |
Effects of flow rate and starvation of reactant gases on the performance of phosphoric acid fuel cells
Song RH, Kim CS, Shin DR |
| 294 - 297 |
Highly efficient heat recovery system for phosphoric acid fuel cells used for cooling telecommunication equipment
Ishizawa M, Okada S, Yamashita T |
| 298 - 301 |
PAFC operating performance verified by Japanese gas utilities
Kasahara K, Morioka M, Yoshida H, Shingai H |
| 302 - 308 |
Optimisation of the cell shape for industrial MCFC stacks
Arato E, Bosio B, Massa R, Parodi F |
| 309 - 315 |
Analysis by electrochemical impedance spectroscopy of new MCFC cathode materials
Perez FJ, Duday D, Hierro MP, Gomez C, Romero M, Casais MT, Alonso JA, Martinez MJ, Daza L |
| 316 - 323 |
Assessment of commercial prospects of molten carbonate fuel cells
Dicks A, Siddle A |
| 324 - 328 |
Long-term corrosion resistance of Al-Ni-plated material and Al-plated material in molten carbonate environment
Kawabata Y, Fujimoto N, Yamamoto M, Nagoya T, Nishida M |
| 329 - 333 |
Modified nickel oxides as cathode materials for MCFC
Daza L, Rangel CM, Baranda J, Casais MT, Martinez MJ, Alonso JA |
| 334 - 339 |
A study of carbon deposition on fuel cell power plants -morphology of deposited carbon and catalytic metal in carbon deposition reactions on stainless steel
Sone Y, Kishida H, Kobayashi M, Watanabe T |
| 340 - 346 |
Properties of NiO cathode coated with lithiated Co and Ni solid solution oxide for MCFCs
Fukui T, Ohara S, Okawa H, Hotta T, Naito M |
| 347 - 351 |
High-performance electrodes for reduced temperature solid oxide fuel cells with doped lanthanum gallate electrolyte II. La(Sr)CoO3 cathode
Inagaki T, Miura K, Yoshida H, Maric R, Ohara S, Zhang X, Mukai K, Fukui T |
| 352 - 362 |
Dry layer preparation and characterisation of polymer electrolyte fuel cell components
Gulzow E, Schulze M, Wagner N, Kaz T, Reissner R, Steinhilber G, Schneider A |
| 423 - 431 |
Evaluation and modeling of performance of anode-supported solid oxide fuel cell
Yakabe H, Hishinuma M, Uratani M, Matsuzaki Y, Yasuda I |
| 432 - 441 |
Pre-reforming of natural gas in solid oxide fuel-cell systems
Peters R, Riensche E, Cremer P |
| 442 - 448 |
Combined solid oxide fuel cell and gas turbine systems for efficient power and heat generation
Palsson J, Selimovic A, Sjunnesson L |
| 449 - 454 |
The influence of the mass transfer on the geometric design of SOFC stacks
Winkler W |
| 455 - 458 |
High performance electrodes for reduced temperature solid oxide fuel cells with doped lanthanum gallate electrolyte I. Ni-SDC cermet anode
Ohara S, Maric R, Zhang X, Mukai K, Fukui T, Yoshida H, Inagaki T, Miura K |
| 459 - 463 |
SOFC system with integrated catalytic fuel processing
Finnerty C, Tompsett GA, Kendall K, Ormerod RM |
| 464 - 468 |
Studies on methanol fuel cell
Verma LK |
| 469 - 477 |
Process engineering of the direct methanol fuel cell
Dohle H, Divisek J, Jung R |
| 478 - 481 |
Electrooxidation of methanol on Pt-Ru catalysts supported by basal plane graphite in phosphoric acid solution
Lee CH, Lee CW, Kim DI, Jung DH, Kim CS, Shin DR |
| 482 - 494 |
Assessment of the environmental benefits of transport and stationary fuel cells
Bauen A, Hart D |
| 495 - 500 |
An integrated SOFC plant dynamic model for power systems simulation
Padulles J, Ault GW, McDonald JR |
| 501 - 506 |
A study of SOFC-PEM hybrid systems
Dicks AL, Fellows RG, Mescal CM, Seymour C |
| 507 - 514 |
Investigation of a methanol reformer concept considering the particular impact of dynamics and long-term stability for use in a fuel-cell-powered passenger car
Peters R, Dusterwald HG, Hohlein B |
| 515 - 522 |
Modelling the integration of a compact plate steam reformer in a fuel cell system
Cunha J, Azevedo JLT |
| 523 - 530 |
Intrinsic reaction kinetics of methane steam reforming on a nickel/zirconia anode
Dicks AL, Pointon KD, Siddle A |
| 531 - 535 |
Hydrogen production hy steam-iron process
Hacker V, Fankhauser R, Faleschini G, Fuchs H, Friedrich K, Muhr M, Kordesch K |
| 536 - 541 |
Hydrogen generation from biogenic and fossil fuels by autothermal reforming
Rampe T, Heinzel A, Vogel B |
| 542 - 547 |
Methanol infrastructure - will it affect the introduction of SPFC vehicles?
Hart D, Leach MA, Fouquet R, Pearson PJ, Bauen A |
| 548 - 555 |
Hydrogen and methanol: a comparison of safety, economics, efficiencies and emissions
Adamson KA, Pearson P |
| 556 - 561 |
CO2-scrubbing and methanation as purification system for PEFC
Ledjeff-Hey K, Roes J, Wolters R |
| 562 - 567 |
Reduction of oxygen from electrolyte emulsions with high oxygen contents
Kronberger H, Bruckner K, Fabjan C |
