| 1 - 1 |
Preface for 10ELBC proceedings
Wilson D |
| 2 - 11 |
Energy storage devices for future hybrid electric vehicles
Karden E, Ploumen S, Fricke B, Miller T, Snyder K |
| 12 - 21 |
Advanced valve-regulated lead-acid batteries for hybrid vehicle applications
Soria ML, Trinidad F, Lacadena JM, Sanchez A, Valenciano J |
| 22 - 30 |
Charging performance of automotive batteries - An underestimated factor influencing lifetime and reliable battery operation
Sauer DU, Karden E, Fricke B, Blanke H, Thele M, Bohlen O, Schiffer J, Gerschler JB, Kaiser R |
| 31 - 39 |
Modeling of the charge acceptance of lead-acid batteries
Thele M, Schiffer J, Karden E, Surewaard E, Sauer DU |
| 40 - 48 |
Advances in VRLA battery technology for telecommunications
Misra SS |
| 49 - 57 |
Investigation and application of poly siloxane-based gel electrolyte in valve-regulated lead-acid battery
Tang Z, Wang JM, Mao XX, Shao HB, Chen QQ, Xu ZH, Zhang JQ |
| 58 - 65 |
Optimized battery-management system to improve storage lifetime in renewable energy systems
Kaiser R |
| 66 - 78 |
Model prediction for ranking lead-acid batteries according to expected lifetime in renewable energy systems and autonomous power-supply systems
Schiffer J, Sauer DU, Bindner H, Cronin T, Lundsager P, Kaiser R |
| 79 - 89 |
Lead-samarium alloys for positive grids of valve-regulated lead-acid batteries
Chen HY, Li S, Li A, Shu D, Li WS, Dou CL, Wang Q, Xiao GM, Peng SG, Chen S, Zhang W, Wang H |
| 90 - 94 |
A technology for production of a "cureless" paste containing a high concentration of tetrabasic lead sulfate and a low concentration of free lead
Boden DP, Loosemo D |
| 95 - 98 |
Hybrid buses - What their batteries really need to do
Kellaway MJ |
| 99 - 104 |
Remote monitoring of VRLA batteries for telecommunications systems
Tsujikawa T, Matsushima T |
| 105 - 109 |
A study on the reversibility of Pb(II)/PbO2 conversion for the application of flow liquid battery
Peng HY, Chen HY, Li WS, Hu SJ, Li H, Nan JM, Xu ZH |
| 111 - 118 |
Evaluation of carbon materials for use in a direct carbon fuel cell
Hackett GA, Zondlo JW, Svensson R |
| 119 - 125 |
Fuel crossover in direct formic acid fuel cells
Jeong KJ, Miesse CA, Choi JH, Lee J, Han J, Yoon SP, Nam SW, Lim TH, Lee TG |
| 126 - 134 |
Relationships between microstructure and transport properties of proton-conducting porous PVDF membranes
Quartarone E, Carollo A, TomaSi C, Belotti F, Grandi S, Mustarelli P, Magistris A |
| 135 - 142 |
Room temperature hydrogen generation from aqueous ammonia-borane using noble metal nano-clusters as highly active catalysts
Chandra M, Xu Q |
| 143 - 153 |
In situ measurements of water crossover through the membrane for direct methanol fuel cells
Xu C, Zhao TS |
| 154 - 161 |
Crosslinked SPEEK/AMPS blend membranes with high moton conductivit and low methanol diffusion coefficient for DMFC applications
Zhong SL, Cui XJ, Cai HL, Fu TZ, Shao K, Na H |
| 162 - 166 |
A novel composite membranes based on sulfonated montmorillonite modified Nafion((R)) for DMFCs
Lin YF, Yen CY, Hung CH, Hsiao YH, Ma CCM |
| 167 - 171 |
A new fuel cell using aqueous ammonia-borane as the fuel
Zhang XB, Han S, Yan JM, Chandra M, Shioyarna H, Yasuda K, Kuriyama N, Kobayashi T, Xu Q |
| 172 - 177 |
Synthesis and properties of fluorine-containing polybenzi.midazole/montmorillonite nanocomposite membranes for direct methanol fuel cell applications
Chuang SW, Hsu SLC, Hsu CL |
| 178 - 183 |
Chemical synthesis of Ca-doped CeO2 - Intermediate temperature oxide ion electrolytes
Thangadurai V, Kopp P |
| 184 - 190 |
Improvement on the corrosion protection of conductive polymers in pemfc environmets by adhesives
Gonzalez-Rodriguez JG, Lucio-Garcia MA, Nicho ME, Cruz-Silva R, Casales M, Valenzuela E |
| 191 - 199 |
Understanding porous water-transport plates in polymer-electrolyte fuel cells
Weber AZ, Darling RM |
| 200 - 210 |
Experimental evaluation and mathematical modeling of a direct alkaline fuel cell
Verma A, Basu S |
| 211 - 217 |
PEM stack test and analysis in a power system at operational load via ac impedance
Zhu WH, Payne RU, Tatarchuk BJ |
| 218 - 228 |
A two-phase non-isothermal mixed-domain PEM fuel cell model and its application to two-dimensional simulations
Meng H |
| 229 - 235 |
A new phenomenon of a fuel-free current during intermittent fuel flow over Ni-YSZ anode in direct methane SOFCs
Huang TJ, Huang MC |
| 236 - 239 |
Silver-perovskite composite SOFC cathodes processed via mechanofusion
Simner SP, Anderson MD, Templeton JW, Stevenson JW |
| 240 - 250 |
Dynamic behavior of PEM FCPPs under various load conditions and voltage stability analysis for stand-alone residential applications
Uzunoglu M, Onar OC, Alam MS |
| 251 - 257 |
Effect of SiO2-ZrO2 supports prepared by a grafting method on hydrogen production by steam reforming of liquefied natural gas over Ni/SiO2-ZrO2 catalysts
Seo JG, Youn MH, Song IK |
| 258 - 264 |
Inhibition of solid electrolyte interface formation on cathode particles for lithium-ion batteries
Li WT, Lucht BL |
| 265 - 271 |
Surface structure and electrochemical characteristics of plasma-fluorinated petroleum cokes for lithium ion battery
Nakajima T, Shibata S, Naga K, Ohzawa Y, Tressaud A, Durand E, Groult H, Warmont F |
| 272 - 277 |
Synthesis and electrochemical characterization of Li1.05RExCryMn2-x-yO4 spinel as cathode material for rechargeable Li-battery
Xie YT, Yang RD, Yan L, Qi L, Dai KH, He P |
| 278 - 281 |
Sulfides organic polymer: Novel cathode active material for rechargeable lithium batteries
Zhang JY, Kong LB, Zhan LZ, Tang J, Zhan H, Zhou YH, Zhan CM |
| 282 - 287 |
High rate capability of the Mg-doped Li-Mn-O spinel prepared via coprecipitated precursor
Wang XQ, Tanaike O, Kodama M, Hatori H |
