| 1 - 7 |
Poly(1-vinylimidazole)/Pd-impregnated Nafion for direct methanol fuel cell applications
Tian AH, Kim JY, Shi JY, Kim K |
| 8 - 13 |
Preparation and physical/electrochemical characterization of Pt/poly(vinylferrocenium) electrocatalyst for methanol oxidation
Celebi MS, Pekmez K, Ozyoruk H, Yildiz A |
| 14 - 19 |
A phase inversion/sintering process to fabricate nickel/yttria-stabilized zirconia hollow fibers as the anode support for micro-tubular solid oxide fuel cells
Yang NT, Tan XY, Ma ZF |
| 20 - 25 |
Novel copper-based anodes for solid oxide fuel cells with samaria-doped ceria electrolyte
Tavares AC, Kuzin BL, Beresnev SM, Bogdanovich NM, Urumchin EK, Dubitsky YA, Zaopo A |
| 26 - 33 |
Synergistic effects of Ni1-xCox-YSZ and Ni1-xCux-YSZ alloyed cermet SOFC anodes for oxidation of hydrogen and methane fuels containing H2S
Grgicak CM, Pakulska MM, O'Brien JS, Giorgi JB |
| 34 - 42 |
Development of high performance carbon composite catalyst for oxygen reduction reaction in PEM Proton Exchange Membrane fuel cells
Nallathambi V, Lee JW, Kumaraguru SP, Wu G, Popov BN |
| 43 - 48 |
Preparation and electrochemical properties of Sr-doped Nd2NiO4 cathode materials for intermediate-temperature solid oxide fuel cells
Sun LP, Li Q, Zhao H, Huo LH, Grenier JC |
| 49 - 54 |
Polarization measurements of anode-supported solid oxide fuel cells studied by incorporation of a reference electrode
Xiao HM, Reitz TL, Rottmayer MA |
| 55 - 61 |
Electrochemical parameter identification - An efficient method for fuel cell impedance characterisation
Danzer MA, Hofer EP |
| 62 - 68 |
Effect of preparative parameters on the characteristic of poly(vinylidene fluoride)-based microporous layer for proton exchange membrane fuel cells
Ong AL, Bottino A, Capannelli G, Comite A |
| 69 - 75 |
A high conductivity Cs2.5H0.5PMo12O40/polybenzimidazole (PBI)/H3PO4 composite membrane for proton-exchange membrane fuel cells OPE-rating at high temperature
Li MQ, Shao ZG, Scott K |
| 76 - 83 |
Synthesis and characterization of new ternary transition metal sulfide anodes for H2S-powered solid oxide fuel cell
Vorontsov V, Luo JL, Sanger AR, Chuang KT |
| 84 - 91 |
Electro-deposition on carbon black and carbon nanotubes of Pt nanostructured catalysts for methanol oxidation
Paoletti C, Cemmi A, Giorgi L, Giorgi R, Pilloni L, Serra E, Pasquali M |
| 92 - 97 |
Hydrogenation and dehydrogenation of Mg2Co nanoparticles and carbon nanotube composites
Hsieh CT, Wei JL, Lin JY, Chen WY |
| 98 - 108 |
Control-orientated thermal model for proton-exchange membrane fuel cell systems
Vasu G, Tangirala AK |
| 109 - 113 |
Properties and fuel cell performance of a Nafion-based, sulfated zirconia-added, composite membrane
Navarra MA, Abbati C, Scrosati B |
| 114 - 117 |
Anode performance of LST-xCeO(2) for solid oxide fuel cells
Sun XF, Wang SR, Wang ZR, Ye XF, Wen TL, Huang FQ |
| 118 - 125 |
Electrochemical parameter estimation in operating proton exchange membrane fuel cells
Rubio MA, Urquia A, Kuhn R, Dormido S |
| 126 - 132 |
Chemical stability and hydrogen permeation performance of Ni-BaZr0.1Ce0.7Y0.2O3-delta in an H2S-containing atmosphere
Fang SM, Bi L, Wu XS, Gao HY, Chen CS, Liu W |
| 133 - 142 |
Modeling of methane fed solid oxide fuel cells: Comparison between proton conducting electrolyte and oxygen ion conducting electrolyte
Ni M, Leung DYC, Leung MKH |
| 143 - 150 |
Modeling electrochemical partial oxidation of methane for cogeneration of electricity and syngas in solid-oxide fuel cells
Zhu HY, Kee RJ, Pillai MR, Barnett SA |
| 151 - 156 |
Influences of hydrogen evolution on the cell and stack performances of the direct borohydride fuel cell
Liu BH, Li ZP, Zhu JK, Suda S |
| 157 - 163 |
Efficiency and fuel utilization of methane-powered single-chamber solid oxide fuel cells
Hao Y, Goodwin DG |
| 164 - 173 |
Semi-analytical proton exchange membrane fuel cell modeling
Cheddie DF, Munroe NDH |
| 174 - 181 |
Surface modifications of aluminum alloy 5052 for bipolar plates using an electroless deposition process
Bai CY, Chou YH, Chao CL, Lee SJ, Ger MD |
| 182 - 192 |
A numerical investigation of the effects of compression force on PEM fuel cell performance
Su ZY, Liu CT, Chang HP, Li CH, Huang KJ, Sui PC |
| 193 - 204 |
Measurements of current and water distribution for a micro-PEM fuel cell with different flow fields
Hsieh SS, Huang YJ |
| 205 - 213 |
On flow uniformity in various interconnects and its influence to cell performance of planar SOFC
Huang CM, Shy SS, Lee CH |
| 214 - 225 |
The effects of the interconnect rib contact resistance on the performance of planar solid oxide fuel cell stack and the rib design optimization
Liu SX, Song C, Lin ZJ |
| 226 - 231 |
Impact of cathode channel depth on performance of direct methanol fuel cells
Hwang SY, Joh HI, Scibioh MA, Lee SY, Kim SK, Lee TG, Ha HY |
| 232 - 239 |
The effect of fuel composition and temperature on the interaction of H2S with nickel-ceria anodes for Solid Oxide Fuel Cells
Lohsoontorn R, Brett DJL, Brandon NP |
| 240 - 246 |
In situ measurements of water transfer due to different mechanisms in a proton exchange membrane fuel cell
Husar A, Higier A, Liu H |
| 247 - 252 |
Conducting oxide formation and mechanical endurance of potential solid-oxide fuel cell interconnects in coal syngas environment
Liu KJ, Luo JH, Johnson C, Liu XB, Yang J, Mao SX |
| 253 - 256 |
Nonlinear predictive control of a molten carbonate fuel cell stack
Yang F, Zhu XJ, Cao GY, Hu WQ |
| 257 - 259 |
Orthogonal flow membraneless fuel cell
Hayes JR, Engstrom AM, Friesen C |
| 260 - 274 |
A review on PEM voltage degradation associated with water management: Impacts, influent factors and characterization
Yousfi-Steiner N, Mocoteguy P, Candusso D, Hissel D, Hernandez A, Aslanides A |
| 275 - 281 |
Drive-train simulator for a fuel cell hybrid vehicle
Brown D, Alexander M, Brunner D, Advani SG, Prasad AK |
| 282 - 294 |
Performance research on the compact heat exchange reformer used for high temperature fuel cell systems
Zhang HS, Wang LJ, Weng SL, Su M |
| 295 - 302 |
Simulation of a fuel reforming system based on catalytic partial oxidation
Hohn KL, DuBois T |
| 303 - 309 |
Zwitterionic imidazolium compounds with high cathodic stability as additives for lithium battery electrolytes
Nguyen DQ, Bae HW, Jeon EH, Lee JS, Cheong M, Kim H, Kim HS, Lee H |
| 310 - 315 |
A high energy Li-ion battery based on nanosized LiNi0.5Mn1.5O4 cathode material
Arrebola JC, Caballero A, Hernan L, Morales J |
| 316 - 324 |
Investigation of LiNi1/3Co1/3Mn1/3O2 cathode particles after 300 discharge/charge cycling in a lithium-ion battery by analytical TEM
Zeng YW |
| 325 - 329 |
Electrochemical characteristics of manganese oxide/carbon composite as a cathode material for Li/MnO2 secondary batteries
Lee J, Lee JM, Yoon S, Kim SO, Sohn JS, Rhee KI, Sohn HJ |
| 330 - 333 |
Hydrothermal synthesis of MoO3 nanobelts utilizing poly(ethylene glycol)
Reddy CVS, Walker EH, Wen C, Mho SI |
| 334 - 338 |
Electrochemical performance of ZnO-coated LiMn1.5Ni0.5O4 cathode material
Singhal R, Tomar MS, Burgos JG, Katiyar RS |
| 339 - 343 |
The role of the morphology in the response of Sb-C nanocomposite electrodes in lithium cells
Hassoun J, Derrien G, Panero S, Scrosati B |
| 344 - 346 |
A new approach to improve the high-voltage cyclic performance of Li-rich layered cathode material by electrochemical pre-treatment
Ito A, Li D, Ohsawa Y, Sato Y |
| 347 - 350 |
Development of non-flammable lithium secondary battery with room-temperature ionic liquid electrolyte: Performance of electroplated Al film negative electrode
Ui K, Yamamoto K, Ishikawa K, Minami T, Takeuchi K, Itagaki M, Watanabe K, Koura N |
| 351 - 354 |
Electrochemical studies on epoxidised natural rubber-based gel polymer electrolytes for lithium-air cells
Mohamed SN, Johari NA, Ali AMM, Harun MK, Yahya MZA |
| 355 - 360 |
Effect of capacity matchup in the LiNi0.5Mn1.5O4/Li4Ti5O12 cells
Xiang HF, Zhang X, Jin QY, Zhang CP, Chen CH, Ge XW |
| 361 - 365 |
Towards real-time (milliseconds) parameter estimation of lithium-ion batteries using reformulated physics-based models
Boovaragavan V, Harinipriya S, Subramanian VR |
| 366 - 369 |
Fabrication and electrochemical characterization of a vertical array of MnO2 nanowires grown on silicon substrates as a cathode material for lithium rechargeable batteries
Kim JH, Ayalasomayajula T, Gona V, Choi D |
| 370 - 375 |
Passive control of temperature excursion and uniformity in high-energy Li-ion battery packs at high current and ambient temperature
Kizilel R, Lateef A, Sabbah R, Farid MM, Selman JR, Al-Hallaj S |
| 376 - 380 |
I. A simplified model for determining capacity usage and battery size for hybrid and plug-in hybrid electric vehicles
Albertus P, Newman J |
| 381 - 387 |
Current and potential distributions on positive plates with conductive Pb3O4 and BaPbO3 in their formation and discharge
Guo YL, Liu H |
| 388 - 398 |
Thermally activated ("thermal") battery technology - Part IV. Anode materials
Guidotti RA, Masset PJ |
| 399 - 402 |
The effect of dispersion of nano-carbon on electrochemical behavior of Fe/nano-carbon composite electrode
Egashira M, Kushizaki JY, Yoshimoto N, Morita M |
| 403 - 405 |
Thermal-to-electric energy conversion of a nanoporous carbon
Qiao Y, Punyamurtual VK, Han A, Lim H |
| 406 - 410 |
Significantly enhanced charge conduction in electric double layer capacitors using carbon nanotube-grafted activated carbon electrodes
Huang CW, Chuang CM, Ting JM, Teng HS |
| 411 - 417 |
Electrochemical performances in temperature for a C-containing LiFePO4 composite synthesized at high temperature
Maccario M, Croguennec L, Le Cras F, Delmas C |
| 418 - 421 |
Mechanochemical synthesis of alpha-Fe2O3 nanoparticles and their application to all-solid-state lithium batteries
Kitaura H, Takahashi K, Mizuno F, Hayashi A, Tadanaga K, Tatsumisago M |
| 422 - 426 |
All-solid-state rechargeable lithium batteries with Li2S as a positive electrode material
Hayashi A, Ohtsubo R, Ohtomo T, Mizuno F, Tatsumisago M |
| 427 - 430 |
Electronic structural changes of the electrochemically delithiated LiFe0.5Co0.5PO4 cathode material studied by X-ray absorption spectroscopy
Yoon WS, Chung KY, Nam KW, McBreen J, Wang DY, Huang XJ, Li H, Chen LQ, Yang XQ |
| 431 - 435 |
Effect of P2O5 in Li2O-P2O5-B2O3 electrolyte fabricated by aerosol flame deposition
Cho K, Oh J, Lee T, Shin D |
| 436 - 440 |
Ionic liquid electrolytes compatible with graphitized carbon negative without additive and their effects on interfacial properties
Sugimoto T, Kikuta M, Ishiko E, Kono M, Ishikawa M |
| 441 - 445 |
Rechargeable lithium/sulfur battery with liquid electrolytes containing toluene as additive
Choi JW, Cheruvally G, Kim DS, Ahn JH, Kim KW, Ahn HJ |
