| 489 - 490 |
Preface for the IBA-HBC 2006
Liaw BY, Yazami R, Blomgren GE, Brodd RJ, Dey AN |
| 491 - 499 |
Review on electrode-electrolyte solution interactions, related to cathode materials for Li-ion batteries
Aurbach D, Markovsky B, Salitra G, Markevich E, Talyossef Y, Koltypin M, Nazar L, Ellis B, Kovacheva D |
| 500 - 508 |
Zinc ion conducting polymer electrolytes based on oligomeric polyether/PVDF-HFP blends
Ye H, Xu JJ |
| 509 - 516 |
Direct NaBH4/H2O2 fuel cells
Miley GH, Luo N, Mather J, Burton R, Hawkins G, Gu LF, Byrd E, Gimlin R, Shrestha PJ, Benavides G, Laystrom J, Carroll D |
| 517 - 534 |
Structural and electrochemical behavior of LiMn0.4Ni0.4Co0.2O2
Ma MM, Chernova NA, Toby BH, Zavalij PY, Whittingham MS |
| 535 - 543 |
Gel polymer electrolyte lithium-ion cells with improved low temperature performance
Smart MC, Ratnakumar BV, Behar A, Whitcanack LD, Yu JS, Alamgir M |
| 544 - 551 |
Recent advances in NiMH battery technology
Fetcenko MA, Ovshinsky SR, Reichman B, Young K, Fierro C, Koch J, Zallen A, Mays W, Ouchi T |
| 552 - 558 |
Evolution of lithiation thermodynamics with the graphitization of carbons
Reynier Y, Yazami R, Fultz B, Barsukov I |
| 559 - 565 |
Development and utility of manganese oxides as cathodes in lithium batteries
Johnson CS |
| 566 - 572 |
Capacity and power fading mechanism identification from a commercial cell evaluation
Dubarry M, Svoboda V, Hwu R, Liaw BY |
| 573 - 580 |
Effect of structure on the storage characteristics of manganese oxide electrode materials
Park YJ, Doeff MM |
| 581 - 590 |
Microporosity of heat-treated manganese dioxide
Arnott JB, Williams RP, Pandolfo AG, Donne SW |
| 591 - 597 |
A miniature microbial fuel cell operating with an aerobic anode chamber
Ringeisen BR, Ray R, Little B |
| 598 - 608 |
Lithium-ion batteries based on carbon-silicon-graphite composite anodes
Khomenko VG, Barsukov VZ, Doninger JE, Barsukov IV |
| 609 - 615 |
New manganese dioxides for lithium batteries
Bowden W, Bofinger T, Zhang F, Iltchev N, Sirotina R, Paik Y, Chen H, Grey C, Hackney S |
| 616 - 619 |
XRD evidence of macroscopic composition inhomogeneities in the graphite-lithium electrode
Reynier Y, Yazami R, Fultz B |
| 620 - 624 |
The dissolution and deposition behavior in lithium powder electrode
Kim JS, Yoon WY, Yi KY, Kim BK, Cho BW |
| 625 - 629 |
Aluminum substituted manganese oxides for lithium battery applications
Machefaux E, Verbaere A, Guyomard D |
| 630 - 634 |
A new chemical approach to improving discharge capacity of Li/(CFx)(n) cells
Nagasubramanian G, Sanchez B |
| 635 - 639 |
Improved high power Li-ion batteries with Li2RuO3 addition: A fast charging and fast cycling study
Stux AM, Swider-Lyons KE |
| 640 - 645 |
Cause of the memory effect in "nickel" electrodes
Huggins RA |
| 646 - 650 |
Improving electrochemical properties of lithium iron phosphate by addition of vanadium
Yang MR, Ke WH, Wu SH |
| 651 - 655 |
Supercapacitor behavior of new substituted manganese dioxides
Machefaux E, Brousse T, Belanger D, Guyomard D |
| 656 - 659 |
Electrochemical properties of LiFePO4 prepared via hydrothermal route
Dokko K, Koizumi S, Sharaishi K, Kanamura K |
| 660 - 665 |
Preparation and characterization of o-LiMnO2 cathode materials
Wu SH, Yu MT |
| 667 - 677 |
Fabrication methods for low-Pt-loading electrocatalysts in proton exchange membrane fuel cell systems
Wee JH, Lee KY, Kim SH |
| 678 - 684 |
Ni-Fe plus SDC composite as anode material for intermediate temperature solid oxide fuel cell
Lu XC, Zhu JH |
| 685 - 691 |
Effect of oxygen and methanol supply modes on the performance of a DMFC employing a porous plate
Abdelkareem MA, Nakagawa N |
| 692 - 700 |
Preparation and properties of high performance nanocomposite proton exchange membrane for fuel cell
Lin YF, Yen CY, Ma CCM, Liao SH, Hung CH, Hsiao YH |
| 701 - 707 |
Morphology study of sulfonated poly(ether ether ketone ketone)s (SPEEKK) membranes: The relationship between morphology and transport properties of SPEEKK membranes
Li XF, Zhang G, Xu D, Zhao CJ, Na H |
| 708 - 716 |
SPEEK/epoxy resin composite membranes in situ polymerization for direct methanol fell cell usages
Fu TZ, Zhao CJ, Zhong SL, Zhang G, Shao K, Zhang HQ, Wang J, Na H |
| 717 - 721 |
Study on the electrical and mechanical properties of phenol formaldehyde resin/graphite composite for bipolar plate
Yin Q, Li AJ, Wang WQ, Xia LG, Wang YM |
| 722 - 727 |
Reactions of low and middle concentration dry methane over Ni/YSZ anode of solid oxide fuel cell
You HX, Abuliti A, Ding XW, Zhou YH |
| 728 - 732 |
Synthesis of nano-crystalline (Ba0.5Sr0.5)Co0.8Fe0.2O3-delta cathode material by a novel sol-gel thermolysis process for IT-SOFCs
Subramania A, Saradha T, Muzhumathi S |
| 733 - 738 |
Preparation of Pt/zeolite-Nafion composite membranes for self-humidifying polymer electrolyte fuel cells
Son DH, Sharma RK, Shul YG, Kim H |
| 739 - 756 |
A review of PEM hydrogen fuel cell contamination: Impacts, mechanisms, and mitigation
Cheng X, Shi Z, Glass N, Zhang L, Zhang JJ, Song DT, Liu ZS, Wang HJ, Shen J |
| 757 - 763 |
Fabrication, microstructure and properties of a YSZ electrolyte for SOFCs
Han MF, Tang XL, Yin HY, Peng SP |
| 764 - 773 |
Development of bipolar plates for fuel cells from graphite filled wet-lay material and a thermoplastic laminate skin layer
Cunningham BD, Huang JH, Baird DG |
| 774 - 785 |
Monte-Carlo simulation and performance optimization for the cathode microstructure in a solid oxide fuel cell
Ji Y, Yuan K, Chung JN |
| 786 - 792 |
Fabrication and characterization of a PTFE-reinforced integral composite membrane for self-humidifying PEMFC
Zhang Y, Zhang HM, Zhu XB, Gang L, Bi C, Liang YM |
| 793 - 802 |
Characterization of transport properties in gas diffusion layers for proton exchange membrane fuel cells 2. Absolute permeability
Gurau V, Bluemle MJ, De Castro ES, Tsou YM, Zawodzinski TA, Mann JA |
| 803 - 813 |
Design for geometric parameters of PEM fuel cell by integrating computational fluid dynamics code with optimization method
Cheng CH, Lin HH, Lai GJ |
| 814 - 818 |
Hydrogen sulfide poisoning and recovery of PEMFC Pt-anodes
Shi WY, Yi BL, Hou M, Jing FN, Ming PW |
| 819 - 832 |
Power management and design optimization of fuel cell/battery hybrid vehicles
Kim MJ, Peng H |
| 833 - 843 |
Fuel cell vehicles: Status 2007
von Helmolt R, Eberle U |
| 844 - 853 |
1 kW(e) sodium borohydride hydrogen generation system Part I: Experimental study
Zhang JS, Zheng Y, Gore JP, Fisher TS |
| 854 - 860 |
Water-gas shift reaction over magnesia-modified Pt/CeO2 catalysts
de Farias AMD, Barandas APMG, Perez RF, Fraga MA |
| 861 - 869 |
Quantifying influence of operational parameters on photocatalytic H-2 evolution over Pt-loaded nanocrystalline mesoporous TiO2 prepared by single-step sol-gel process with surfactant template
Sreethawong T, Puangpetch T, Chavadej S, Yoshikawa S |
| 870 - 873 |
High-rate capable organic radical cathodes for lithium rechargeable batteries
Nakahara K, Iriyama J, Iwasa S, Suguro M, Satoh M, Cairns EJ |
| 874 - 879 |
Design criteria for nanostructured Li-ion batteries
Aifantis KE, Hackney SA, Dempsey JP |
| 880 - 886 |
Comparison of approximate solution methods for the solid phase diffusion equation in a porous electrode model
Zhang Q, White RE |
| 887 - 891 |
Theoretical evaluation of high-energy lithium metal phosphate cathode materials in Li-ion batteries
Howard WF, Spotnitz RM |
| 892 - 896 |
Variables study for the fast charging lithium ion batteries
Park CK, Zhang ZW, Xu ZQ, Kakirde A, Kang K, Chai C, Au G, Cristo L |
| 897 - 904 |
A regenerative zinc-air fuel cell
Smedley SI, Zhang XG |
| 905 - 910 |
Influence of surface modification with Sn6O4(OH)(4) on electrochemical performance of ZnO in Zn/Ni secondary cells
Yuan YF, Tu JP, Wu HM, Zhang CQ, Wang SF, Zhao XB |
| 911 - 915 |
Novel quasi-solid electrolyte for dye-sensitized solar cells
Li FJ, Cheng FY, Shi JF, Cai FS, Liang M, Chen J |
| 916 - 921 |
Effect of synthesis conditions on characteristics of the precursor material used in NiO center dot OH/Ni(OH)(2) electrodes of alkaline batteries
Freitas MBJG, Silva RKSE, Anjos DM, Rozario A, Manoel PG |
| 922 - 927 |
High temperature carbon-carbon supercapacitor using ionic liquid as electrolyte
Balducci A, Dugas R, Taberna PL, Simon P, Plee D, Mastragostino M, Passerini S |
| 928 - 934 |
Frequency, thermal and voltage supercapacitor characterization and modeling
Rafik F, Gualous H, Gallay R, Crausaz A, Berthon A |
