| 1 - 2 |
In Memoriam Professor Klaus Wiesener Obituary
Garche J |
| 3 - 13 |
Materials selection for bipolar plates for polymer electrolyte membrane fuel cells using the Ashby approach
de Oliveira MCL, Ett G, Antunes RA |
| 14 - 19 |
A non-precious metal bifunctional oxygen electrode for alkaline anion exchange membrane cells
Wu X, Scott K |
| 20 - 28 |
Synthesis and characterization of PtCo nanowires for the electro-oxidation of methanol
Bertin E, Garbarino S, Ponrouch A, Guay D |
| 29 - 36 |
Combinatorial screening for methanol oxidation catalysts in alloys of Pt, Cr, Co and V
Zhang Y, McGinn PJ |
| 37 - 46 |
Buckling deformation of polymer electrolyte membrane and membrane electrode assembly under humidity cycles
Uchiyama T, Kato M, Yoshida T |
| 47 - 52 |
Novel triple-phase composite cathode materials for proton-conducting solid oxide fuel cells
Jiang QM, Cheng JG, Wang R, Fan YM, Gao JF |
| 53 - 58 |
Substrate-dependent performance of supercapacitors based on an organic redox couple impregnated on carbon
Isikli S, Diaz R |
| 59 - 69 |
Thermomechanical, transport and anodic properties of perovskite-type (La0.75Sr0.25)(0.95)Cr1-xFexO3-delta
Lu MF, Tsipis EV, Waerenborgh JC, Yaremchenko AA, Kolotygin VA, Bredikhin S, Kharton VV |
| 70 - 76 |
Sandvik Sanergy HT - A potential interconnect material for LaNbO4-based proton ceramic fuel cells
Skilbred AWB, Haugsrud R |
| 77 - 83 |
A composite sol-gel process to prepare a YSZ electrolyte for Solid Oxide Fuel Cells
Courtin E, Boy P, Piquero T, Vulliet J, Poirot N, Laberty-Robert C |
| 84 - 90 |
Experimental study of single triple-phase-boundary and platinum-yttria stabilized zirconia composite as cathodes for micro-solid oxide fuel cells
Yan Y, Sandu SC, Conde J, Muralt P |
| 91 - 96 |
The effect of an ultra-thin zirconia blocking layer on the performance of a 1-mu m-thick gadolinia-doped ceria electrolyte solid-oxide fuel cell
Myung DH, Hong J, Yoon K, Kim BK, Lee HW, Lee JH, Son JW |
| 97 - 102 |
The importance of water in the polyol synthesis of carbon supported platinum-tin oxide catalysts for ethanol electrooxidation
Liu B, Chia ZW, Lee ZY, Cheng CH, Lee JY, Liu ZL |
| 103 - 107 |
Effect of Se in Co-based selenides towards oxygen reduction electrocatalytic activity
Zhao DJ, Zhang S, Yin GP, Du CY, Wang ZB, Wei J |
| 108 - 110 |
Nano zirconium oxide/carbon black as a new electrode material for electrochemical double layer capacitors
Nasibi M, Golozar MA, Rashed G |
| 111 - 118 |
Fabrication and characterization of a Sm0.2Ce0.8O1.9 electrolyte film by the spin-coating method for a low-temperature anode-supported solid oxide fuel cells
Yang RJ, Lee MC, Chang JC, Lin TN, Chang YC, Kao WX, Lee LS, Cheng SW |
| 119 - 128 |
Droplet dynamics in a polymer electrolyte fuel cell gas flow channel: Forces, deformation, and detachment. I: Theoretical and numerical analyses
Cho SC, Wang Y, Chen KS |
| 129 - 143 |
A comprehensive yet comprehensible analytical model for the direct methanol fuel cell
Rosenthal NS, Vilekar SA, Datta R |
| 144 - 152 |
Innovative model-based control approach of a proton exchange membrane fuel cell system
Damour C, Grondin D, Benne M, Grondin-Perez B, Deseure J, Chabriat JP |
| 153 - 160 |
Absolute permeability and Knudsen diffusivity measurements in PEMFC gas diffusion layers and micro porous layers
Pant LM, Mitra SK, Secanell M |
| 161 - 170 |
Impact of gas stoichiometry on water management and fuel cell performance of a sulfonated Poly(Ether Ether Ketone) membrane
Legrand PM, Morin A, Mareau VH, Gonon L |
| 171 - 178 |
A modified dusty gas model in the form of a Fick's model for the prediction of multicomponent mass transport in a solid oxide fuel cell anode
Kong W, Zhu HY, Fei ZY, Lin ZJ |
| 179 - 184 |
Fabrication of micro-flow channels for metallic bipolar plates by a high-pressure hydroforming apparatus
Hung JC, Lin CC |
| 185 - 196 |
Investigation of thermal radiation effects on solid oxide fuel cell performance by a comprehensive model
Zeng M, Yuan JL, Zhang J, Sunden B, Wang QW |
| 197 - 203 |
Optimization studies of a polymer electrolyte membrane fuel cell with multiple catalyst layers
Srinivasarao M, Bhattacharyya D, Rengaswamy R |
| 204 - 209 |
Thermo-mechanical properties of (Sr,Y)TiO3 as anode material for solid oxide fuel cells
Huang BX, Vasechko V, Ma QL, Malzbender J |
| 210 - 214 |
Characteristics and performance improvement of anode supported solid oxide fuel cells based on BaIn(0.)3Ti(0.7)O(2.85) (BIT07) as electrolyte, BIT07-Ni as anode and La0.58Sr0.4Co0.2Fe0.8O3-delta (LSCF) as cathode
Letilly M, Joubert O, La Salle AL |
| 215 - 221 |
Analysis of biogas reforming process for molten carbonate fuel cells
Chiodo V, Urbani F, Galvagno A, Mondello N, Freni S |
| 222 - 229 |
Preparation of carbon-coated LiFe0.2Mn0.8PO4 cathode material and its application in a novel battery with Li4Ti5O12 anode
Zou QQ, Zhu GN, Xia YY |
| 230 - 235 |
High performance of LiNi0.5Mn0.5O2 positive electrode boosted by ordered three-dimensional nanostructures
Liu YM, Cao F, Chen BL, Zhao XZ, Suib SL, Chan HLW, Yuan JK |
| 236 - 244 |
Lithium metal electrode kinetics and ionic conductivity of the solid lithium ion conductors "Li7La3Zr2O12" and Li7-xLa3Zr2-xTaxO12 with garnet-type structure
Buschmann H, Berendts S, Mogwitz B, Janek J |
| 245 - 252 |
Investigation on the part played by the solid electrolyte interphase on the electrochemical performances of the silicon electrode for lithium-ion batteries
Ulldemolins M, Le Cras F, Pecquenard B, Phan VP, Martin L, Martinez H |
| 253 - 258 |
Germanium nanowires-based carbon composite as anodes for lithium-ion batteries
Tan LP, Lu ZY, Tan HT, Zhu JX, Rui XH, Yan QY, Hng HH |
| 259 - 266 |
LiFePO4-Fe2P-C composite cathode: An environmentally friendly promising electrode material for lithium-ion battery
Rahman MM, Wang JZ, Zeng R, Wexler D, Liu HK |
| 267 - 273 |
Fabrication of Si core/C shell nanofibers and their electrochemical performances as a lithium-ion battery anode
Lee BS, Son SB, Park KM, Seo JH, Lee SH, Choi IS, Oh KH, Yu WR |
| 274 - 281 |
First-principles studies of the effects of impurities on the ionic and electronic conduction in LiFePO4
Hoang K, Johannes MD |
| 282 - 287 |
Electrochemical performance of the nanostructured biotemplated V2O5 cathode for lithium-ion batteries
Pomerantseva E, Gerasopoulos K, Chen XY, Rubloff G, Ghodssi R |
| 288 - 294 |
Hierarchically textured LixMn2-yO4 thin films as positive electrodes for lithium-ion batteries
Bettge M, Ryu SY, MacLaren S, Burdin S, Petrov I, Yu MF, Sammann E, Abraham DP |
| 295 - 300 |
Effect of surface preparation and R-group size on the stabilization of lithium metal anodes with silanes
Neuhold S, Schroeder DJ, Vaughey JT |
| 301 - 309 |
Percolating networks of TiO2 nanorods and carbon for high power lithium insertion electrodes
Bresser D, Paillard E, Binetti E, Krueger S, Striccoli M, Winter M, Passerini S |
| 310 - 314 |
A novel way to calculate energy efficiency for rechargeable batteries
Kang JQ, Yan FW, Zhang P, Du CQ |
| 315 - 319 |
Effect of substitution (Ta, Al, Ga) on the conductivity of Li7La3Zr2O12
Allen JL, Wolfenstine J, Rangasamy E, Sakamoto J |
| 320 - 324 |
In situ Raman study on degradation of edge plane graphite negative-electrodes and effects of film-forming additives
Nakagawa H, Domi Y, Doi T, Ochida M, Tsubouchi S, Yamanaka T, Abe T, Ogumi Z |
| 325 - 333 |
Nano SiO2 particle formation and deposition on polypropylene separators for lithium-ion batteries
Fu D, Luan B, Argue S, Bureau MN, Davidson IJ |
| 334 - 342 |
Real-time stress measurements in lithium-ion battery negative-electrodes
Sethuraman VA, Van Winkle N, Abraham DP, Bower AF, Guduru PR |
| 343 - 348 |
The influence of particle size and spacing on the fragmentation of nanocomposite anodes for Li batteries
Dimitrijevic BJ, Aifantis KE, Hackl K |
| 349 - 356 |
Three-dimensional thermal modeling of a lithium-ion battery pack
Sun HG, Wang XH, Tossan B, Dixon R |
| 357 - 366 |
Method to deduce the critical size for interfacial delamination of patterned electrode structures and application to lithiation of thin-film silicon islands
Haftbaradaran H, Xiao XC, Verbrugge MW, Gao HJ |
| 367 - 377 |
Discrete-time realization of transcendental impedance models, with application to modeling spherical solid diffusion
Leek JL, Chemistruck A, Plett GL |
| 378 - 382 |
Rate-based degradation modeling of lithium-ion cells
Thomas EV, Bloom I, Christophersen JP, Battaglia VS |
| 383 - 392 |
Module design and fault diagnosis in electric vehicle batteries
Offer GJ, Yufit V, Howey DA, Wu B, Brandon NP |
| 393 - 401 |
Product recovery from Li-ion battery wastes coming from an industrial pre-treatment plant: Lab scale tests and process simulations
Granata G, Moscardini E, Pagnanelli F, Trabucco F, Toro L |
| 402 - 408 |
High temperature versus low temperature Zebra (Na/NiCl2) cell performance
Hosseinifar M, Petric A |
| 409 - 413 |
A composite of sulfur and polypyrrole-multi walled carbon combinatorial nanotube as cathode for Li/S battery
Liang X, Wen ZY, Liu Y, Zhang H, Jin J, Wu MF, Wu XW |
| 414 - 420 |
An investigation of heavy metal content from disposable batteries of non-U.S. origin from Butler County, Ohio: An environmental assessment of a segment of a waste stream
Barrett HA, Ferraro A, Burnette C, Meyer A, Krekeler MPS |
| 421 - 428 |
Analysis of pressure variations in a low-pressure nickel-hydrogen battery. Part 2: Cells with metal hydride storage
Purushothaman BK, Wainright JS |
| 429 - 435 |
Analysis of pressure variations in a low-pressure nickel-hydrogen battery: Part 1
Purushothaman BK, Wainright JS |
| 436 - 449 |
What properties of grid energy storage are most valuable?
Hittinger E, Whitacre JF, Apt J |
| 450 - 453 |
Dramatic performance gains in vanadium redox flow batteries through modified cell architecture
Aaron DS, Liu Q, Tang Z, Grim GM, Papandrew AB, Turhan A, Zawodzinski TA, Mench MM |
| 454 - 462 |
In situ crystallographic investigations of charge storage mechanisms in MnO2-based electrochemical capacitors
Ghodbane O, Ataherian F, Wu NL, Favier F |
| 463 - 468 |
Using eggshell membrane as a separator in supercapacitor
Yu HJ, Tang QQ, Wu JH, Lin YZ, Fan LQ, Huang ML, Lin JM, Li Y, Yu FD |
| 469 - 475 |
Designing tunable microstructures of Mn3O4 nanoparticles by using surfactant-assisted dispersion
Lee YF, Chang KH, Hu CC, Chu YH |
| 476 - 482 |
Graphene based supercapacitor fabricated by vacuum filtration deposition
Zhang SL, Li YM, Pan N |
| 483 - 489 |
Practical and commercial issues in the design and manufacture of vanadium flow batteries
Schreiber M, Harrer M, Whitehead A, Bucsich H, Dragschitz M, Seifert E, Tymciw P |
| 490 - 496 |
Degradation mechanisms in the non-aqueous vanadium acetylacetonate redox flow battery
Shinkle AA, Sleightholme AES, Griffith LD, Thompson LT, Monroe CW |
| 497 - 503 |
Evaluation of carbon composite materials for the negative electrode in the zinc-cerium redox flow cell
Nikiforidis G, Berlouis L, Hall D, Hodgson D |
