| 1 - 1 |
Ernst Voss - In memorium
Ruetschi P |
| 2 - 8 |
Preparation and characterization of composite membranes composed of zirconium tricarboxybutylphosphonate and polybenzimidazole for intermediate temperature operation
Jang MY, Yamazaki Y |
| 9 - 14 |
Structural control and impedance analysis of cathode for direct methanol fuel cell
Furukawa K, Okajima K, Sudoh M |
| 15 - 20 |
The behavior of palladium catalysts in direct formic acid fuel cells
Zhu YM, Khan Z, Masel RI |
| 21 - 29 |
A random resistor network analysis on anodic performance enhancement of solid oxide fuel cells by penetrating electrolyte structures
Jeon DH, Nam JH, Kim CJ |
| 30 - 34 |
Pt catalyst configuration by a new plating process for a micro tubular DMFC cathode
Qiao H, Kunimatsu M, Okada T |
| 35 - 43 |
A modeling investigation on the electrochemical behavior of porous mixed conducting cathodes for solid oxide fuel cells
Zeng YW, Tian CG, Bao LM |
| 44 - 54 |
Carbon-supported Pt-Ru catalysts prepared by the Nafion stabilized alcohol-reduction method for application in direct methanol fuel cells
Sarma LS, Lin TD, Tsai YW, Chen JM, Hwang BJ |
| 55 - 60 |
Thermodynamic analysis of carbon formation in a solid oxide fuel cell with a direct internal reformer fuelled by methanol
Assabumrungrat S, Laosiripojana N, Pavarajarn V, Sangtongkitcharoen W, Tangjitmatee A, Praserthdam P |
| 61 - 66 |
Preparation of platinum electrocatalysts using carbon supports for oxygen reduction at a gas-diffusion electrode
Gharibi H, Mirzaie RA, Shams E, Zhiani M, Khairmand M |
| 67 - 72 |
Fabrication and characterization of anode-supported electrolyte thin films for intermediate temperature solid oxide fuel cells
Kim SD, Hyun SH, Moon J, Kim JH, Song RH |
| 73 - 78 |
Carbon-supported Pt nanoparticles as catalysts for proton exchange membrane fuel cells
Liu ZL, Gan LM, Hong L, Chen WX, Lee JY |
| 79 - 90 |
In situ visualization study of CO2 gas bubble behavior in DMFC anode flow fields
Yang H, Zhao TS, Ye Q |
| 91 - 95 |
Microchennel development for autothermal reforming of hydrocarbon fuels
Bae JM, Ahmed S, Kumar R, Doss E |
| 96 - 105 |
Fabrication and preliminary testing of a planar membraneless microchannel fuel cell
Cohen JL, Westly DA, Pechenik A, Abruna HD |
| 106 - 114 |
Real-time water distribution in a polymer electrolyte fuel cell
Dong Q, Kull J, Mench MM |
| 115 - 125 |
Predictions of internal temperature distribution of PEMFC by non-destructive inverse method
Cheng CH, Chang MH |
| 126 - 140 |
Integrated thermal engineering analyses with heat transfer at periphery of planar solid oxide fuel cell
Chyou YP, Chung TD, Chen JS, Shie RF |
| 141 - 151 |
Synthesis, characterization, and conductivity measurements of hybrid membranes containing a mono-lacunary heteropolyacid for PEM fuel cell applications
Vernon DR, Meng FQ, Dec SF, Williamson DL, Turner JA, Herring AM |
| 152 - 164 |
Direct hydrogen fuel cell systems for hybrid vehicles
Ahluwalia RK, Wang X |
| 165 - 169 |
Evolutionary programming-based methodology for economical output power from PEM fuel cell for micro-grid application
El-Sharkh MY, Rahman A, Alam MS |
| 170 - 175 |
Operation of thin Nafion-based self-humidifying membranes in proton exchange membrane fuel cells with dry H-2 andO(2)
Yang B, Fu YZ, Manthiram A |
| 176 - 181 |
Autoreduction of promoted Ni/gamma-Al2O3 during autothermal reforming of methane
Dias JAC, Assaf JM |
| 182 - 187 |
Oxidation of Haynes 230 alloy in reduced temperature solid oxide fuel cell environments
Jian L, Jian P, Xiao JH, Qian XL |
| 188 - 196 |
Life cycle assessment of fuel cell-based APUs
Baratto F, Diwekar UM |
| 197 - 204 |
Multi-objective trade-offs for fuel cell-based auxiliary power units: case study of South California Air Basin
Baratto F, Diwekar UM |
| 205 - 213 |
Impacts assessment and trade-offs of fuel cell-based auxiliary power units Part I: System performance and cost modeling
Baratto F, Diwekar UM, Manca D |
| 214 - 222 |
Impacts assessment and tradeoffs of fuel cell based auxiliary power units Part II. Environmental and health impacts, LCA, and multi-objective optimization
Baratto F, Diwekar UA, Manca D |
| 223 - 229 |
A novel comb-like copolymer based polymer electrolyte for Li batteries
Wang MK, Qi L, Zhao F, Dong SJ |
| 230 - 234 |
Improved electrochemical performance of Li-doped natural graphite anode for lithium secondary batteries
Lee YT, Yoon CS, Sun YK |
| 235 - 241 |
Novel porous separator based on PVdF and PE non-woven matrix for rechargeable lithium batteries
Lee YM, Kim JW, Choi NS, Lee JA, Seol WH, Park JK |
| 242 - 249 |
Pyrolysis of hexa(phenyl)benzene derivatives: a molecular approach toward carbonaceous materials for Li-ion storage
Renouard T, Gherghel L, Wachtler M, Bonino F, Scrosati B, Nuffer R, Mathis C, Mullen K |
| 250 - 260 |
Anodic behaviour and X-ray photoelectron spectroscopy of ternary tin oxides
Sharma N, Shaju KM, Rao GVS, Chowdari BVR |
| 261 - 268 |
Kinetic analysis of the Li+ ion intercalation behavior of solution derived nano-crystalline lithium manganate thin films
Das SR, Majumder SB, Katiyar RS |
| 269 - 273 |
Electrochemical characterization and performance improvement of lithium/sulfur polymer batteries
Zhu XJ, Wen ZY, Gu ZH, Lin ZX |
| 274 - 278 |
Improved cycling performance of bismuth-modified amorphous manganese oxides as cathodes for rechargeable lithium batteries
Yang JS, Atwater TB, Xu JJ |
| 279 - 283 |
Vibrational analysis of lithium nickel vanadate
Bhuvaneswari MS, Selvasekarapandian S, Kamishima O, Kawamura J, Hattori T |
| 284 - 288 |
Effect of unreacted monomer on performance of lithium-ion polymer batteries based on polymer electrolytes prepared by free radical polymerization
Lee KH, Lim HS, Wang JH |
| 289 - 294 |
Direct carbon-black coating on LiCoO2 cathode using surfactant for high-density Li-ion cell
Kim J, Kim B, Lee JG, Cho J, Park B |
| 295 - 303 |
Differential voltage analyses of high-power, lithium-ion cells 1. Technique and application
Bloom I, Jansen AN, Abraham DP, Knuth J, Jones SA, Battaglia VS, Henriksen GL |
| 304 - 313 |
Differential voltage analyses of high-power lithium-ion cells 2. Applications
Bloom I, Christophersen J, Gering K |
| 314 - 320 |
Porous silicon negative electrodes for rechargeable lithium batteries
Shin HC, Corno JA, Gole JL, Liu ML |
| 321 - 324 |
Investigations on V(IV)/V(V) and V(II)/V(III) redox reactions by various electrochemical methods
Oriji G, Katayama Y, Miura T |
| 325 - 341 |
Hydrothermal MnO2: synthesis, structure, morphology and discharge performance
Walanda DK, Lawrance GA, Donne SW |
| 342 - 350 |
Defining high power EMD through porosimetry
Davis SM, Bowden WL, Richards TC |
| 351 - 355 |
Ionic conductance behavior of polymeric gel electrolyte containing ionic liquid mixed with magnesium salt
Morita M, Shirai T, Yoshimoto N, Ishikawa M |
| 356 - 365 |
Retained molten salt electrolytes in thermal batteries
Masset P, Schoeffert S, Poinso JY, Poignet JC |
| 366 - 370 |
Electrochemical recovery of cadmium from spent Ni-Cd batteries
Freitas MBJG, Rosalem SF |
| 371 - 378 |
Influence of carbon nanotubes addition on carbon-carbon supercapacitor performances in organic electrolyte
Portet C, Taberna PL, Simon P, Flahaut E |
| 379 - 383 |
Electric double-layer capacitance of microporous carbon nano spheres prepared through precipitation of aromatic resin pitch
Lee SI, Mitani S, Park CW, Yoon SH, Korai Y, Mochida I |
| 384 - 393 |
Effect of plasticizer on structure - property relationship in composite polymer electrolytes
Pradhan DK, Samantaray BK, Choudhary RNP, Thakur AK |
