| 189 - 193 |
Concentration polarisation in heterogeneous electrochemical reactions: a consistent kinetic evaluation and its application to molten carbonate fuel cells
Bosio B, Arato E, Costa P |
| 194 - 202 |
Fabrication of gas-diffusion electrodes at various pressures and investigation of synergetic effects of mixed electrocatalysts on oxygen reduction reaction
Gharibi H, Mirzaie RA |
| 203 - 209 |
The characteristics of power generation of static state fuel cells
Shen MZ, Meuleman W, Scott K |
| 210 - 218 |
Simulation of process for electrical energy production based on molten carbonate fuel cells
De Simon G, Parodi F, Fermeglia M, Taccani R |
| 219 - 228 |
Conditioning effects on La1-xSrxMnO3-yttria stabilized zirconia electrodes for thin-film solid oxide fuel cells
Lee YK, Kim JY, Lee YK, Kim I, Moon HS, Park JW, Jacobson CP, Visco SJ |
| 229 - 235 |
Catalysts for direct formic acid fuel cells
Rice C, Ha S, Masel RI, Wieckowski A |
| 236 - 242 |
Investigation of PEM type direct hydrazine fuel cell
Yamada K, Asazawa K, Yasuda K, Ioroi T, Tanaka H, Miyazaki Y, Kobayashi T |
| 243 - 251 |
Stainless steel as bipolar plate material for polymer electrolyte membrane fuel cells
Wang HL, Sweikart MA, Turner JA |
| 252 - 267 |
Hybrid systems for distributed power generation based on pressurisation and heat recovering of an existing 100 kW molten carbonate fuel cell
Grillo O, Magistri L, Massardo AF |
| 268 - 273 |
An innovative process for PEMFC electrodes using the expansion of Nafion film
Hsu CH, Wan CC |
| 274 - 278 |
Mid-term stability of novel mica-based compressive seals for solid oxide fuel cells
Chou YS, Stevenson JW |
| 279 - 287 |
Design and testing of a fuel-cell powered battery charging station
Jiang ZH, Dougal RA |
| 288 - 294 |
SM2O3 composite PEO solid polymer electrolyte
Chu PP, Reddy MJ |
| 295 - 304 |
Effect of glass-ceramic filler on properties of polyethylene oxide-LiCF3SO3 complex
Leo CJ, Thakur AK, Rao GVS, Chowdari BVR |
| 305 - 314 |
Effects of aluminum on the structural and electrochemical properties of LiNiO2
Guilmard M, Rougier A, Grune A, Croguennec L, Delmas C |
| 315 - 322 |
LiMn2O4-based composites processed by a chemical-route microstructural, electrical, electrochemical, and mechanical characterization
Lazarraga MG, Mandal S, Ibanez J, Amarilla JM, Rojo JM |
| 323 - 331 |
To the electrochemistry of pyrite in Li/solid composite-polymer-electrolyte battery
Strauss E, Golodnitsky D, Freedman K, Milner A, Peled E |
| 332 - 345 |
Preparation and electrochemical properties of high-voltage cathode materials, LiMyNi0.5-yMn1.5O4 (M = Fe, Cu, Al, Mg; y=0.0-0.4)
Fey GTK, Lu CZ, Kumar TP |
| 346 - 351 |
Amorphous silicon anode for lithium-ion rechargeable batteries
Jung HJ, Park M, Yoon YG, Kim GB, Joo SK |
| 352 - 359 |
Recovery of heavy metals from spent Ni-Cd batteries by a potentiostatic electrodeposition technique
Yang CC |
| 360 - 366 |
Nanostructured thermal batteries with high power density
Au M |
| 367 - 373 |
Recovery of zinc and manganese from spent alkaline batteries by liquid-liquid extraction with Cyanex 272
Salgado AL, Veloso AMO, Pereira DD, Gontijo GS, Salum A, Mansur MB |
