| 127 - 127 |
Untitled
Moseley PT |
| 128 - 141 |
The role of carbon in fuel cells
Dicks AL |
| 142 - 150 |
Graphite and carbon powders for electrochemical applications
Wissler M |
| 151 - 157 |
Polymeric composite bipolar plates for vehicle applications
Blunk R, Elhamid MHA, Lisi D, Mikhail Y |
| 158 - 165 |
TiO2-coated Ni powder as a new cathode material for molten carbonate fuel cells
Hong MZ, Lee HS, Kim MH, Park EJ, Ha HW, Kim K |
| 166 - 170 |
Synthesis and decomposition reactions of metal amides in metal-N-H hydrogen storage system
Leng HY, Ichikawa T, Hino S, Hanada N, Isobe S, Fujii H |
| 171 - 182 |
Progress in preparation of non-noble electrocatalysts for PEM fuel cell reactions
Zhang L, Zhang JJ, Wilkinson DP, Wang HJ |
| 183 - 189 |
Anode reaction mechanism and crossover in direct dimethyl ether fuel cell
Mizutani I, Liu Y, Mitsushima S, Ota KI, Kamiya N |
| 190 - 194 |
A high-performance hydrogen generation system: Transition metal-catalyzed dissociation and hydrolysis of ammonia-borane
Chandra M, Xu Q |
| 195 - 199 |
NMR investigation of water and methanol transport in sulfonated polyareylenethioethersulfones for fuel cell applications
Jayakody JRP, Khalfan A, Mananga ES, Greenbaum SG, Dang TD, Mantz R |
| 200 - 210 |
Preparation of radiochemically pore-filled polymer electrolyte membranes for direct methanol fuel cells
Nasef MM, Zubir NA, Ismail AF, Dahlan KZM, Saidi H, Khayet M |
| 211 - 223 |
Computational study of water transport in proton exchange membrane fuel cells
Um S, Wang CY |
| 224 - 231 |
Effects of sputtering parameters on the performance of electrodes fabricated for proton exchange membrane fuel cells
Huang KL, Lai YC, Tsai CH |
| 232 - 243 |
Modeling and optimization of the air system in polymer exchange membrane fuel cell systems
Bao C, Ouyang M, Yi BL |
| 244 - 252 |
Numerical study of reactant gas transport phenomena and cell performance of proton exchange membrane fuel cells
Jang JH, Yan WM, Shih CC |
| 253 - 259 |
Silicon-based miniaturized-reformer for portable fuel cell applications
Kwon OJ, Hwang SM, Ahn JG, Kim JJ |
| 260 - 266 |
Effect of magnesium on preferential oxidation of carbon monoxide on platinum catalyst in hydrogen-rich stream
Cho SH, Park JS, Choi SH, Kim SH |
| 267 - 280 |
Water flooding and two-phase flow in cathode channels of proton exchange membrane fuel cells
Liu X, Guo H, Ma CF |
| 281 - 283 |
Activation of proton-exchange membrane fuel cells via CO oxidative stripping
Xu ZQ, Qi ZG, Kaufman A |
| 284 - 287 |
Compact dynamic hydrogen electrode unit as a reference electrode for PEMFCs
Siroma Z, Kakitsubo R, Fujiwara N, Ioroi T, Yamazaki SI, Yasuda K |
| 288 - 293 |
Performance of a unit cell equipped with a modified catalytic reformer in direct internal reforming-molten carbonate fuel cell
Wee JH |
| 294 - 299 |
Operation of a proton-exchange membrane fuel cell under non-humidified conditions using thin cast Nafion membranes with different gas-diffusion media
Vengatesan S, Kim HJ, Cho EA, Jeong SU, Ha HY, Oh IH, Hong SA, Lim TH |
| 300 - 305 |
Preparation, characterization and utilization of a new electrocatalyst for ethanol oxidation obtained by the sol-gel method
Calegaro ML, Suffredini HB, Machado SAS, Avaca LA |
| 306 - 310 |
Anode-supported SOFC with 1Ce10ScZr modified cathode/electrolyte interface
Wang ZW, Cheng MJ, Dong YL, Zhang M, Zhang HM |
| 311 - 314 |
Novel proton-conducting polymer electrolyte membranes based on PVA/PAMPS/PEG400 blend
Hamaya T, Inoue S, Qiao JL, Okada T |
| 315 - 320 |
Combined activation methods for proton-exchange membrane fuel cells
Xu ZQ, Qi ZG, He CZ, Kaufman A |
| 321 - 333 |
Techno-economic modelling of a solid oxide fuel cell stack for micro combined heat and power
Hawkes AD, Aguiar P, Hernandez-Aramburo CA, Leach MA, Brandon NP, Green TC, Adjiman CS |
| 334 - 344 |
Computational analysis of heat and mass transfer in a micro-structured PEMFC cathode
Litster S, Pharoah JG, McLean G, Djilali N |
| 345 - 354 |
Development of PtRu-CeO2/C anode electrocatalyst for direct methanol fuel cells
Guo JW, Zhao TS, Prabhuram J, Chen R, Wong CW |
| 355 - 368 |
Predicting the transient response of a serpentine flow-field PEMFC I. Excess to normal fuel and air
Shimpalee S, Lee WK, Van Zee JW, Naseri-Neshat H |
| 369 - 374 |
Predicting the transient response of a serpentine flow-field PEMFC II: Normal to minimal fuel and AIR
Shimpalee S, Lee WK, Zee JW, Naseri-Neshat H |
| 375 - 387 |
Capillary pressure and hydrophilic porosity in gas diffusion layers for polymer electrolyte fuel cells
Gostick JT, Fowler MW, Ioannidis MA, Pritzker MD, Volfkovich YM, Sakars A |
| 388 - 399 |
Toward the optimization of operating conditions for hydrogen polymer electrolyte fuel cells
Wu JX, Liu QY, Fang HB |
| 400 - 413 |
Computer experimental analysis of the CHP performance of a 100 kW(e) SOFC Field Unit by a factorial design
Cali M, Santarelli MGL, Leone P |
| 414 - 423 |
Parametric model of an intermediate temperature PEMFC
Cheddie D, Munroe N |
| 424 - 433 |
Main and interaction effects of PEM fuel cell design parameters
Guvelioglu GH, Stenger HG |
| 434 - 447 |
Gas-phase reactions of methane and natural-gas with air and steam in non-catalytic regions of a solid-oxide fuel cell
Gupta GK, Hecht ES, Zhu HY, Dean AM, Kee RJ |
| 448 - 454 |
Analysis and minimization of input ripple current in PWM inverters for designing reliable fuel cell power systems
Shireen W, Kulkarni RA, Arefeen A |
| 455 - 460 |
Development and testing of anode-supported solid oxide fuel cells with slurry-coated electrolyte and cathode
Muccillo R, Muccillo ENS, Fonseca FC, Franca YV, Porfirio TC, de Florio DZ, Berton MAC, Garcia CM |
| 461 - 465 |
Identification of nickel sulfides on Ni-YSZ cermet exposed to H-2 fuel containing H2S using Raman spectroscopy
Dong J, Cheng Z, Zha SW, Liu ML |
| 466 - 471 |
Nano-structured Pt-Cr anode catalyst over carbon support, for direct methanol fuel cell
Choi JS, Chung WS, Ha HY, Lim TH, Oh IH, Hong SA, Lee HI |
| 472 - 479 |
Analysis of stationary fuel cell dynamic ramping capabilities and ultra capacitor energy storage using high resolution demand data
Meacham JR, Jabbari F, Brouwer J, Mauzey JL, Samuelsen GS |
| 480 - 488 |
Hydrogen and dry ice production through phase equilibrium separation and methane reforming
Posada A, Manousiouthakis V |
| 489 - 496 |
Simulation of a low temperature water gas shift reactor using the heterogeneous model/application to a pem fuel cell
Giunta P, Amadeo N, Laborde M |
| 497 - 511 |
Dimethyl ether (DME) as an alternative fuel
Semelsberger TA, Borup RL, Greene HL |
| 512 - 519 |
Critical flow rate of anode fuel exhaust in a PEM fuel cell system
Zhu WHH, Payne RU, Tatarchuk BJ |
| 520 - 524 |
Hydrogen generation from 2,2,4-trimethyl pentane reforming over molybdenum carbide at low steam-to-carbon ratios
Cheekatamarla PK, Thomson WJ |
| 525 - 532 |
Lithium ion and electronic conductivity in 3-(oligoethylene oxide)thiophene comb-like polymers
Witker D, Curtis MD |
| 533 - 540 |
Redox behavior of nanohybrid material with defined morphology: Vanadium oxide nanotubes intercalated with polyaniline
Malta M, Louarn G, Errien N, Torresi RM |
| 541 - 546 |
Thermal study on single electrodes in lithium-ion battery
Huang Q, Yan MM, Jiang ZY |
| 547 - 554 |
Decomposition reaction of LiPF6-based electrolytes for lithium ion cells
Kawamura T, Okada S, Yamaki J |
| 555 - 559 |
Thermal behavior and decomposition kinetics of six electrolyte salts by thermal analysis
Lu ZR, Yang L, Guo YJ |
| 560 - 566 |
Solid-state Li/LiFePO4 polymer electrolyte batteries incorporating an ionic liquid cycled at 40 degrees C
Shin JH, Henderson WA, Scaccia S, Prosini PP, Passerini S |
| 567 - 573 |
A chemometric investigation of the effect of the process parameters on the performance of mixed Si/C electrodes
Dimov N, Noguchi H, Yoshio M |
| 574 - 580 |
Gel-type polymer electrolytes with different types of ceramic fillers and lithium salts for lithium-ion polymer batteries
Yang CM, Kim HS, Na BK, Kum KS, Cho BW |
| 581 - 588 |
Enhanced electrochemical properties of PEO-based composite polymer electrolyte with shape-selective molecular sieves
Xi JY, Qiu XP, Cui MZ, Tang XZ, Zhu WT, Chen LQ |
| 589 - 593 |
Lithium ion conductivity of gel polymer electrolytes containing insoluble lithium tetrakis(pentafluorobenzenethiolato) borate
Aoki T, Ohta T, Fujinami T |
| 594 - 597 |
Phosphides with zinc blende structure as anodes for lithium-ion batteries
Kishore MVVMS, Varadaraju UV |
| 598 - 603 |
Influence of magnetic properties on electrochemical activity of LiNi0.5Fe0.5O2
Kalpana D, Joseyphus RJ, Venkateswaran C, Narayanasamy A, Ananth MV |
| 604 - 609 |
Electrochemical properties of silicon deposited on patterned wafer
Bang B, Kim MH, Moon HS, Lee YK, Park JW |
| 610 - 614 |
Functionalized polythiophene-coated textile: A new anode material for a flexible battery
Wang CY, Ballantyne AM, Hall SB, Too CO, Officer DL, Wallace GG |
| 615 - 619 |
Exfoliation-induced nanoribbon formation of poly(3,4-ethylene dioxythiophene) PEDOT between MoS2 layers as cathode material for lithium batteries
Murugan AV, Quintin M, Delville MH, Campet G, Gopinath CS, Vijayamohanan K |
| 620 - 628 |
Review of models for predicting the cycling performance of lithium ion batteries
Santhanagopalan S, Guo QZ, Ramadass P, White RE |
| 629 - 633 |
Enhanced performance of Li-ion cell with LiBF4-PC based electrolyte by addition of small amount of LiBOB
Zhang SS, Xu K, Jow TR |
| 634 - 644 |
Is 3-methyl-2-oxazolidinone a suitable solvent for lithium-ion batteries?
Gzara L, Chagnes A, Carre B, Dhahbi M, Lemordant D |
| 645 - 654 |
Modelling of primary alkaline battery cathodes: A simplified model
Johansen JF, Farrell TW, Please CP |
| 655 - 661 |
Synthesis of nickel hydroxide: Effect of precipitation conditions on phase selectivity and structural disorder
Ramesh TN, Kamath PV |
| 662 - 666 |
Development of high-capacity nickel-metal hydride batteries using superlattice hydrogen-absorbing alloys
Yasuoka S, Magari Y, Murata T, Tanaka T, Ishida J, Nakamura H, Nohma T, Kihara M, Baba Y, Teraoka H |
| 667 - 672 |
High-rate dischargeability enhancement of Ni/MH rechargeable batteries by addition of nanoscale CoO to positive electrodes
Wu JB, Tu JP, Han TA, Yang YZ, Zhang WK, Zhao XB |
| 673 - 676 |
Electrochemical insertion of magnesium in open-ended vanadium oxide nanotubes
Jiao LF, Yuan HT, Si YC, Wang YJ, Cao JS, Gao XL, Zhao M, Zhou XD, Wang YM |
| 677 - 684 |
Thermodynamic analysis of electrokinetic energy conversion
Xuan XC, Li DQ |
| 685 - 691 |
Optimization of the TIEC/AMTEC cascade cell for high efficiency
Lodhi MAK, Malka VR |
| 692 - 699 |
Investigation of the porosity of electrolytic manganese dioxide and its performance as alkaline cathode material
Qu DY |
| 700 - 704 |
Porous structured vanadium oxide electrode material for electrochemical capacitors
Reddy RN, Reddy RG |
| 705 - 711 |
Analysis of polyaniline-based nickel electrodes for electrochemical supercapacitors
Girija TC, Sangaranarayanan MV |
| 712 - 718 |
Influence of temperature and electrolyte on the performance of activated-carbon supercapacitors
Liu P, Verbrugge M, Soukiazian S |
| 719 - 724 |
Influence of mesophase activation conditions on the specific capacitance of the resulting carbons
Mora E, Ruiz V, Santamaria R, Blanco C, Granda A, Menendez R, Juarez-Galan JM, Rodriguez-Reinoso F |
| 725 - 740 |
Requirements for performance characterization of C double-layer supercapacitors: Applications to a high specific-area C-cloth material
Niu JJ, Pell WG, Conway BE |
| 741 - 747 |
Production of capacitive films from Mn thin films: Effects of current density and film thickness
Djurfors B, Broughton JN, Brett MJ, Ivey DG |
| 748 - 754 |
Resistance distribution in electrochemical capacitors with spiral-wound structure
Zheng JP, Jiang ZN |
| 755 - 762 |
An ultracapacitor circuit for reducing sulfation in lead acid batteries for Mild Hybrid Electric Vehicles
Stienecker AW, Stuart T, Ashtiani C |
