| 1 - 11 |
A mathematical model for PEMFC in different flow modes
Ge SH, Yi BL |
| 12 - 17 |
A direct 2-propanol polymer electrolyte fuel cell
Cao DX, Bergens SH |
| 18 - 25 |
Proton-conducting composite membranes derived from sulfonated hydrocarbon and inorganic materials
Chang JH, Park JH, Park GG, Kim CS, Park OO |
| 26 - 33 |
Sinterability and ionic conductivity of coprecipitated Ce0.8Gd0.2O2-delta powders treated via a high-energy ball-milling process
Zhang TS, Ma J, Kong LB, Hing P, Leng YJ, Chan SH, Kilner JA |
| 34 - 39 |
Direct alcohol fuel cell - relation between the cell performance and the adsorption of intermediate originating in the catalyst-fuel combinations
Kobayashi T, Otomo J, Wen CJ, Takahashi H |
| 40 - 46 |
Fabrication of miniature silicon wafer fuel cells with improved performance
Yu JR, Cheng P, Ma ZQ, Yi BL |
| 47 - 51 |
Preparation and characterization of matrix retaining electrolyte for a phosphoric acid fuel cell by non-volatile solvent, NMP
Yoon KH, Yang BD |
| 52 - 58 |
Effects of fluoride on the performance of MCFCs
Kawase M, Mugikura Y, Izaki Y, Watanabe T, Ito Y |
| 59 - 64 |
A modified Nafion membrane with in situ polymerized polypyrrole for the direct methanol fuel cell
Smit MA, Ocampo AL, Espinosa-Medina MA, Sebastian PJ |
| 65 - 75 |
Combinations of solid oxide fuel cell and several enhanced gas turbine cycles
Kuchonthara P, Bhattacharya S, Tsutsumi A |
| 76 - 80 |
Fast start-up reactor for partial oxidation of methane with electrically-heated metallic monolith catalyst
Jung H, Yoon WL, Lee H, Park JS, Shin JS, La H, Lee JD |
| 81 - 89 |
Development of novel self-humidifying composite membranes for fuel cells
Liu FQ, Yi BL, Xing DM, Yu JR, Hou ZJ, Fu YZ |
| 90 - 98 |
In situ water distribution measurements in a polymer electrolyte fuel cell
Mench MM, Dong QL, Wang CY |
| 99 - 103 |
Characterization of the activity and stability of supported cobalt catalysts for the steam reforming of ethanol
Batista MS, Santos RKS, Assaf EM, Assaf JM, Ticianelli EA |
| 104 - 113 |
Modeling and simulation of the dynamic behavior of a polymer electrolyte membrane fuel cell
Yerramalla S, Davari A, Feliachi A, Biswas T |
| 114 - 117 |
Fabrication of high precision PEFC membrane electrode assemblies
Bender G, Zawodzinski TA, Saab AP |
| 118 - 123 |
LiCoO2 sub-microns particles obtained from micro-precipitation in molten stearic acid
Lala SM, Montoro LA, Rosolen JM |
| 124 - 132 |
Chemical transformation of the electrode surface of lithium-ion battery after storing at high temperature
Araki K, Sato N |
| 133 - 142 |
Self-assembled monolayers of diphenyl disulphide: a novel cathode material for rechargeable lithium batteries
Maddanimath T, Khollam YB, Aslam A, Mulla IS, Vijayamohanan K |
| 143 - 147 |
Two-step addition of acetylene black to hydrated sodium manganese oxide: its effect on the performance of rapid discharge cathode
Hibino M, Kawaoka H, Zhou HS, Honma I |
| 148 - 154 |
Thermal, mechanical, swelling, and electrochemical properties of poly(vinylidene fluoride)-co-hexafluoropropylene/poly(ethylene glycol) hybrid-type polymer electrolytes
Chung NK, Kwon YD, Kim D |
| 155 - 162 |
Synthesis, characterization and cycling performance of novel chromium oxide cathode materials for lithium batteries
Ramasamy RP, Ramadass P, Haran BS, Popov BN |
| 163 - 169 |
Characterization and preparation of NiO-V2O5 composite film cathodes
Liu HR, Chu YQ, Fu ZW, Qin QZ |
| 170 - 173 |
All-solid-state lithium secondary batteries using a layer-structured LiNi0.5Mn0.5O2 cathode material
Mizuno F, Hayashi A, Tadanaga K, Minami T, Tatsumisago M |
| 174 - 181 |
Electrochemical characteristics of rancieite-type manganese oxide by mechanochemical synthesis
Woo SG, Kim H, Lee CK, Sohn HJ, Kang T |
| 182 - 190 |
Electrochemical performance and cyclability of LiFe0.5Mn1.5O4 as a 5 V cathode material for lithium batteries
Eftekhari A |
| 191 - 196 |
Rate capability of natural Swedish graphite as anode material in Li-ion batteries
Herstedt A, Fransson L, Edstrom K |
| 197 - 203 |
Electrochemical characterization of a polypyffole/Co0.2CrOx composite as a cathode material for lithium ion batteries
Ramasamy RP, Veeraraghavan B, Haran B, Popov BN |
| 204 - 212 |
Iron-tin oxides with CaFe2O4 structure as anodes for Li-ion batteries
Sharma N, Shaju KM, Rao GVS, Chowdari BVR |
| 213 - 220 |
On the use of voltammetric methods to determine electrochemical stability limits for lithium battery electrolytes
Georen P, Lindbergh G |
| 221 - 224 |
Electrochemical and physical properties of composite polymer electrolyte of poly(methyl methacrylate) and poly(ethylene glycol diacrylate)
Kim HS, Kum KS, Cho WI, Cho BW, Rhee HW |
| 225 - 230 |
Effect of salt concentration in poly(vinyl alcohol)-based solid polymer electrolytes
Rajendran S, Sivakumar M, Subadevi R |
| 231 - 236 |
LiTi2(PO4)(3) with NASICON-type structure as lithium-storage materials
Wang GX, Bradhurst DH, Dou SX, Liu HK |
| 237 - 240 |
On the cycle behavior of various graphitic negative electrodes in a propylene carbonate-based electrolyte for lithium ion batteries
Egashira M, Okada S, Yamaki J |
| 241 - 245 |
CaSi2 as an anode for lithium-ion batteries
Wolfenstine J |
| 246 - 253 |
Hot-pressed, solvent-free, nanocomposite, PEO-based electrolyte membranes II. All solid-state Li/LiFePO4 polymer batteries
Appetecchi GB, Hassoun J, Scrosati B, Croce F, Cassel F, Salomon M |
| 254 - 260 |
Accelerated power degradation of Li-ion cells
Thomas EV, Case HL, Doughty DH, Jungst RG, Nagasubramanian G, Roth EP |
| 261 - 265 |
Investigation of cycle life of Li-LixV2O5 rechargeable batteries
Moss PL, Fu R, Au G, Plichta EJ, Xin Y, Zheng JP |
| 266 - 270 |
Reaction between lead oxide and lignin in aqueous solution
Saito K, Hirai N, Shiota M, Yamaguchi Y, Nakayama Y, Hara S |
| 271 - 277 |
Studies of current and potential distributions on lead-acid batteries - I. Discharge of automotive flooded positive plates
Guo YL, Li Y, Zhang GD, Zhang HM, Garche J |
| 278 - 284 |
Studies on the oxygen reduction catalyst for zinc-air battery electrode
Wang XY, Sebastian PJ, Smit MA, Yang HP, Gamboa SA |
| 285 - 292 |
Research of Mm(NiMnAlCu)(4.9)Co-0.2 hydrogen storage alloys prepared by cast and rapidly quenched
Li P, Zhang YH, Wang XL, Lin YF, Qu XH |
| 293 - 298 |
Mathematic simulation on thermoelectric power generation with cylindrical multi-tubes
Suzuki RO, Tanaka D |
| 299 - 302 |
Novel vanadium chloride/polyhalide redox flow battery
Skyllas-Kazacos M |
| 303 - 308 |
A novel dry bipolar rechargeable battery based on polyaniline
Karami H, Mousavi MF, Shamsipur M |
| 309 - 313 |
Electrochemical characterization of a hydride-forming metal alloy surface-modified with palladium
Barsellini D, Visintin A, Triaca WE, Soriaga MP |
| 314 - 320 |
Evaluation of nafion based double layer capacitors by electrochemical impedance spectroscopy
Lufrano F, Staiti P, Minutoli M |
| 321 - 329 |
Investigation of electrochemical double-layer (ECDL) capacitors electrodes based on carbon nanotubes and activated carbon materials
Emmenegger C, Mauron P, Sudan P, Wenger P, Hermann V, Gallay R, Zuttel A |
| 330 - 337 |
Sol-gel MnO2 as an electrode material for electrochemical capacitors
Reddy RN, Reddy RG |
| 338 - 342 |
Characteristics of tantalum electrolytic capacitors using soluble polypyrrole electrolyte
Jang KS, Moon BJ, Oh EJ, Lee HS |
| 343 - 350 |
Fabrication of microcapacitors using conducting polymer microelectrodes
Sung JH, Kim SJ, Lee KH |
| 351 - 354 |
All-solid supercapacitor based on polyaniline and sulfonated poly(ether ether ketone)
Sivaraman P, Hande VR, Mishra VS, Rao CS, Samui AB |
| 355 - 359 |
Electrochemical behavior of the polypyrrole/polyimide composite by potential step amperometry
Levine KL, Iroh JO |
