| 877 - 885 |
Lithium insertion/extraction mechanism in alloy anodes for lithium-ion batteries
Zhang WJ |
| 886 - 893 |
Review on Li-air batteries-Opportunities, limitations and perspective
Kraytsberg A, Ein-Eli Y |
| 894 - 898 |
Enhanced conductivity and stability of composite membranes based on poly (2,5-benzimidazole) and zirconium oxide nanoparticles for fuel cells
Zheng HT, Mathe M |
| 899 - 904 |
Improved performance of air-cathode microbial fuel cell through additional Tween 80
Wen Q, Kong FY, Ma F, Ren YM, Pan Z |
| 905 - 910 |
Exploring proton transfer in 1,2,3-triazole-triazolium dimer with ab initio method
Li AL, Yan TY, Shen PW |
| 911 - 919 |
Nanostructured membranes and electrodes with sulfonic acid functionalized carbon nanotubes
Tripathi BP, Schieda M, Shahi VK, Nunes SP |
| 920 - 927 |
Polyol synthesis of nanosized Pt/C electrocatalysts assisted by pulse microwave activation
Lebegue E, Baranton S, Coutanceau C |
| 928 - 934 |
Performance of (La,Sr)MnO3 cathode based solid oxide fuel cells: Effect of bismuth oxide sintering aid in silver paste cathode current collector
Gong YH, Ji WJ, Zhang L, Xie B, Wang HQ |
| 935 - 945 |
Comparison of numerical simulation results with experimental current density and methanol-crossover data for direct methanol fuel cells
Ko J, Lee G, Choi Y, Chippar P, Kang K, Ju H |
| 946 - 955 |
Crosslinked poly(vinyl alcohol)/sulfonated poly(ether ether ketone) blend membranes for fuel cell applications-Surface energy characteristics and proton conductivity
Kanakasabai P, Vijay P, Deshpande AP, Varughese S |
| 956 - 961 |
Hydrazine electrooxidation on a composite catalyst consisting of nickel and palladium
Ye LQ, Li ZP, Qin HY, Zhu JK, Liu BH |
| 962 - 967 |
Micro-tubular solid oxide fuel cells with graded anodes fabricated with a phase inversion method
Zhao L, Zhang XZ, He BB, Liu BB, Xia CR |
| 968 - 976 |
Anode- versus electrolyte-supported Ni-YSZ/YSZ/Pt SOFCs: Effect of cell design on OCV, performance and carbon formation for the direct utilization of dry methane
Buccheri MA, Singh A, Hill JM |
| 977 - 987 |
Effects of bi-layer La0.6Sr0.4Co0.2Fe0.8O3-delta-based cathodes on characteristics of intermediate temperature solid oxide fuel cells
Wang SF, Wang YR, Yeh CT, Hsu YF, Chyou SD, Lee WT |
| 988 - 998 |
Preparation and characterization of phosphotungstic acid-derived salt/Nafion nanocomposite membranes for proton exchange membrane fuel cells
Amirinejad M, Madaeni SS, Navarra MA, Rafiee E, Scrosati B |
| 999 - 1005 |
Bi0.5Sr0.5MnO3 as cathode material for intermediate-temperature solid oxide fuel cells
Liu BB, Jiang ZY, Ding B, Chen FL, Xia CR |
| 1006 - 1011 |
X-ray photoemission spectroscopy analysis of N-containing carbon-based cathode catalysts for polymer electrolyte fuel cells
Niwa H, Kobayashi M, Horiba K, Harada Y, Oshima M, Terakura K, Ikeda T, Koshigoe Y, Ozaki J, Miyata S, Ueda S, Yamashita Y, Yoshikawa H, Kobayashi K |
| 1012 - 1018 |
Preparation and characterization of Pt supported on graphene with enhanced electrocatalytic activity in fuel cell
Xin YC, Liu JG, Zhou Y, Liu WM, Gao JA, Xie Y, Yin Y, Zou ZG |
| 1019 - 1029 |
Study on local morphological changes of nickel in solid oxide fuel cell anode using porous Ni pellet electrode
Jiao ZJ, Takagi N, Shikazono N, Kasagi N |
| 1030 - 1035 |
Experimental analysis of pulsing techniques in a proton exchange fuel cell
Perez A, Abtahi A, Zilouchian A |
| 1036 - 1041 |
Ethane dehydrogenation over nano-Cr2O3 anode catalyst in proton ceramic fuel cell reactors to co-produce ethylene and electricity
Fu XZ, Luo XX, Luo JL, Chuang KT, Sanger AR, Krzywicki A |
| 1042 - 1047 |
Investigation of carbon supported Au-Ni bimetallic nanoparticles as electrocatalyst for direct borohydride fuel cell
He PY, Wang Y, Wang XY, Pei F, Wang H, Liu L, Yi LH |
| 1048 - 1054 |
Fast proton-conducting glass membrane based on porous phosphosilicate and perfluorosulfonic acid polymer
Jiang FJ, Di ZG, Li HB, Tu HY, Yu QC |
| 1055 - 1060 |
New process for high temperature polybenzimidazole membrane production and its impact on the membrane and the membrane electrode assembly
Liu ZY, Tsou YM, Calundann G, De Castro E |
| 1061 - 1068 |
Nafion-based composite electrolytes for proton exchange membrane fuel cells operating above 120 degrees C with titania nanoparticles and nanotubes as fillers
Matos BR, Santiago EI, Rey JFQ, Ferlauto AS, Traversa E, Linardi M, Fonseca FC |
| 1069 - 1077 |
Alternative hybrid electrolytes based on a series of bis(trialkoxysilyl)alkanes and 3-(trihydroxysilyl)-1-propane sulfonic acid applied in gas diffusion electrodes of proton exchange membrane fuel cells
Lin CW, Chung LC, Veerapur RS, Yang FC |
| 1078 - 1083 |
Study of core-shell platinum-based catalyst for methanol and ethylene glycol oxidation
Kaplan D, Alon M, Burstein L, Rosenberg Y, Peled E |
| 1084 - 1089 |
An investigation of Pt alloy oxygen reduction catalysts in phosphoric acid doped PBI fuel cells
Mamlouk M, Scott K |
| 1090 - 1096 |
PtxSn/C electrocatalysts synthesized by imporved microemulsion method and their catalytic activity for ethanol oxidation
Li LR, Huang MH, Liu JJ, Guo YL |
| 1097 - 1102 |
Mesh optimization for microbial fuel cell cathodes constructed around stainless steel mesh current collectors
Zhang F, Merrill MD, Tokash JC, Saito T, Cheng S, Hickner MA, Logan BE |
| 1103 - 1106 |
Polyaniline/carbon black composite-supported iron phthalocyanine as an oxygen reduction catalyst for microbial fuel cells
Yuan Y, Ahmed J, Kim S |
| 1107 - 1111 |
A miniature passive direct formic acid fuel cell based twin-cell stack with highly stable and reproducible long-term discharge performance
Hong P, Liao SJ, Zeng JH, Zhong YL, Liang ZX |
| 1112 - 1117 |
Investigation the addition of silicon oxide to carbon: Effects of amount and heat treatment on anti-aggregation and electrochemical performance of Pt catalysts
Wu YN, Liao SJ, Zeng JH |
| 1118 - 1122 |
High efficient electrooxidation of formic acid at a novel Pt-indole composite catalyst prepared by electrochemical self-assembly
Zhou WQ, Wang CY, Xu JK, Du YK, Yang P |
| 1123 - 1126 |
A Nafion-silica cathode electrolyte for durable elevated-temperature direct methanol fuel cells
Lei M, Wang SL, Li LH, Tang WH |
| 1127 - 1131 |
Carbon supported Pt-Y electrocatalysts for the oxygen reduction reaction
Jeon MK, McGinn PJ |
| 1132 - 1135 |
The electrochemical oxidation of methanol on a Pt/TNTs/Ti electrode enhanced by illumination
Wang YQ, Wei ZD, Gao B, Qi XQ, Li L, Zhang Q, Xia MR |
| 1136 - 1140 |
Influence of microstructure of perovskite-type oxide cathodes on electrochemical performances of proton-conducting solid oxide fuel cells operated at low temperature
Asamoto M, Yamaura H, Yahiro H |
| 1141 - 1144 |
Studies on the electrochemical reduction of oxygen catalyzed by reduced graphene sheets in neutral media
Wu JJ, Wang Y, Zhang D, Hou BR |
| 1145 - 1155 |
Pore-network simulations of two-phase flow in a thin porous layer of mixed wettability: Application to water transport in gas diffusion layers of proton exchange membrane fuel cells
Kuttanikkad SP, Prat M, Pauchet J |
| 1156 - 1162 |
A high performance ceria based interdiffusion barrier layer prepared by spin-coating
Plonczak P, Joost M, Hjelm J, Sogaard M, Lundberg M, Hendriksen PV |
| 1163 - 1170 |
A comparison of high-speed flywheels, batteries, and ultracapacitors on the bases of cost and fuel economy as the energy storage system in a fuel cell based hybrid electric vehicle
Doucette RT, McCulloch MD |
| 1171 - 1177 |
Power management system for a 2.5W remote sensor powered by a sediment microbial fuel cell
Donovan C, Dewan A, Peng HA, Heo D, Beyenal H |
| 1178 - 1183 |
Comparative exergy analysis of direct alcohol fuel cells using fuel mixtures
Leo TJ, Raso MA, Navarro E, Sanchez-de-la-Blanca E |
| 1184 - 1190 |
Anode-supported microtubular cells fabricated with gadolinia-doped ceria nanopowders
Gil V, Gurauskis J, Campana R, Merino RI, Larrea A, Orera VM |
| 1191 - 1204 |
Exergy analysis of a passive direct methanol fuel cell
Bahrami H, Faghri A |
| 1205 - 1215 |
Fuel cell system modeling for solid oxide fuel cell/gas turbine hybrid power plants, Part I: Modeling and simulation framework
Leucht F, Bessler WG, Kallo J, Friedrich KA, Muller-Steinhagen H |
| 1216 - 1221 |
Service life estimation of liquid silicone rubber seals in polymer electrolyte membrane fuel cell environment
Cui T, Lin CW, Chien CH, Chao YJ, Van Zee JW |
| 1222 - 1228 |
Multi-objective topology optimization of end plates of proton exchange membrane fuel cell stacks
Lin P, Zhou P, Wu CW |
| 1229 - 1234 |
A membraneless microfluidic fuel cell stack
Salloum KS, Posner JD |
| 1235 - 1241 |
Effect of manufacturing conditions on the corrosion resistance behavior of mettalic bipolar plates in proton exchange membrance fuel cells
Dur E, Cora ON, Koc M |
| 1242 - 1247 |
Preparation of fibrous Ni-coated-YSZ anodes for solid oxide fuel cells
Li LP, Zhang PG, Liu RR, Guo SM |
| 1248 - 1257 |
Stochastic reconstruction and scaling method to determine effective transport coefficients of a proton exchange membrane fuel cell catalyst layer
Barbosa R, Andaverde J, Escobar B, Cano U |
| 1258 - 1263 |
Chromium nitride/Cr coated 316L stainless steel as bipolar plate for proton exchange membrane fuel cell
Tian RJ |
| 1264 - 1272 |
A potentially implantable glucose fuel cell with Raney-platinum film electrodes for improved hydrolytic and oxidative stability
Kerzenmacher S, Kraling U, Metz T, Zengerle R, von Stetten F |
| 1273 - 1278 |
Optimizing operating conditions and electrochemical characterization of glucose-gluconate alkaline fuel cells
Pasta M, La Mantia F, Ruffo R, Peri F, Della Pina C, Mari CM |
| 1279 - 1294 |
Microstructure degradation of cermet anodes for solid oxide fuel cells: Quantification of nickel grain growth in dry and in humid atmospheres
Holzer L, Iwanschitz B, Hocker T, Munch B, Prestat M, Wiedenmann D, Vogt U, Holtappels P, Sfeir J, Mai A, Graule T |
| 1295 - 1302 |
Power decoupling control of a solid oxide fuel cell and micro gas turbine hybrid power system
Wu XJ, Huang Q, Zhu XJ |
| 1303 - 1313 |
Mechanical behavior of the membrane during the polymer electrolyte fuel cell operation
Serincan MF, Pasaogullari U |
| 1314 - 1320 |
Effect of gas diffusion layer anisotropy on mechanical stresses in a polymer electrolyte membrane
Serincan MF, Pasaogullari U |
| 1321 - 1323 |
Can crystalline phases be self-healing sealants for solid oxide fuel cells?
Zhang T, Tang DA, Yang HW |
| 1324 - 1328 |
Carbon supported ruthenium chalcogenide as cathode catalyst in a microfluidic formic acid fuel cell
Gago AS, Morales-Acosta D, Arriaga LG, Alonso-Vante N |
| 1329 - 1332 |
A quinhydrone biofuel cell based on an enzyme-induced pH gradient
Giroud F, Gondran C, Gorgy K, Pellissier A, Lenouvel F, Cinquin P, Cosnier S |
| 1333 - 1337 |
Simulation of coarsening in three-phase solid oxide fuel cell anodes
Chen HY, Yu HC, Cronin JS, Wilson JR, Barnett SA, Thornton K |
| 1338 - 1341 |
A novel bilayered Sr0.6La0.4TiO3/La0.8Sr0.2MnO3 interconnector for anode-supported tubular solid oxide fuel cell via slurry-brushing and co-sintering process
Xu YJ, Wang SR, Liu RZ, Wen TL, Wen ZY |
| 1342 - 1348 |
2D-correlation analysis applied to in situ and operando Mossbauer spectroscopy
Aldon L, Perea A |
| 1349 - 1352 |
Advanced nickel metal catalyst for water-gas shift reaction
Hwang KR, Lee CB, Park JS |
| 1353 - 1357 |
Improvement of electrochemical propertis of Li1.1Al0.05Mn1.85O4 achieved by an AlF3 coating
Lee DJ, Lee KS, Myung ST, Yashiro H, Sun YK |
| 1358 - 1364 |
Electrical and electrochemical studies of poly(vinylidene fluoride)-clay nanocomposite gel polymer electrolytes for Li-ion batteries
Deka M, Kumar A |
| 1365 - 1370 |
Li-7 nuclear magnetic resonance studies of hard carbon and graphite/hard carbon anode for Li ion battery
Fujimoto H, Mabuchi A, Tokumitsu K, Chinnasamy N, Kasuh T |
| 1371 - 1377 |
The influence of the nitrogen-ion flux on structure and ionic conductivity of vapor deposited lithium phosphorus oxynitride films
Kim YG, Wadley HNG |
| 1378 - 1385 |
Synthesis, structure and electrochemical Li insertion behaviour of Li2Ti6O13 with the Na2Ti6O13 tunnel-structure
Perez-Flores JC, Kuhn A, Garcia-Alvarado F |
| 1386 - 1391 |
Liquid electrolytes based on new lithium conductive imidazole salts
Niedzicki L, Kasprzyk M, Kuziak K, Zukowska GZ, Marcinek M, Wieczorek W, Armand M |
| 1392 - 1398 |
Modification of the LixV2O5 phase diagram by incorporation of chromium oxide
Pereira-Ramos JP, Soudan P, Baddour-Hadjean R, Bach S |
| 1399 - 1408 |
Cathode performance of LiMnPO4/C nanocomposites prepared by a combination of spray pyrolysis and wet ball-milling followed by heat treatment
Doan TNL, Taniguchi I |
| 1409 - 1416 |
Improved cycling stability of silicon thin film electrodes through patterning for high energy density lithium batteries
Xiao X, Liu P, Verbrugge MW, Haftbaradaran H, Gao H |
| 1417 - 1424 |
Electrochemical characterizaiton of electrolytes for lithium-ion batteries based on lithium difluoromono(oxalato)borate
Zugmann S, Moosbauer D, Amereller M, Schreiner C, Wudy F, Schmitz R, Schmitz R, Isken P, Dippel C, Muller R, Kunze M, Lex-Balducci A, Winter M, Gores HJ |
| 1425 - 1432 |
Inorganic-organic polymer electrolytes based on poly(vinyl alcohol) and borane/Poly(ethylene glycol) monomethyl ether for Li-ion batteries
Aydin H, Senel M, Erdemi H, Baykal A, Tulu M, Ata A, Bozkurt A |
| 1433 - 1441 |
One ether-functionalized guanidinium ionic liquid as new electrolyte for lithium battery
Fang SH, Tang YF, Tai XY, Yang L, Tachibana K, Kamijima K |
| 1442 - 1448 |
Strain accommodation and potential hysteresis of LiFePO4 cathodes during lithium ion insertion/extraction
Zhu YJ, Wang CS |
| 1449 - 1454 |
Mechanochemical synthesis of metallic Ag2F and application to Ag3MoO3F3 based nanocomposites for lithium batteries
Tong W, Amatucci GG |
| 1455 - 1460 |
Vertically aligned carbon nanotube electrodes for lithium-ion batteries
Welna DT, Qu LT, Taylor BE, Dai LM, Durstock MF |
| 1461 - 1468 |
Copper sulfates as cathode materials for Li batteries
Schwieger JN, Kraytsberg A, Ein-Eli Y |
| 1469 - 1473 |
SnCo nanowire array as negative electrode for lithium-ion batteries
Ferrara G, Damen L, Arbizzani C, Inguanta R, Piazza S, Sunseri C, Mastragostino M |
| 1474 - 1477 |
Whisker formation on a thin film tin lithium-ion battery anode
Li JC, Yang FQ, Ye J, Cheng YT |
| 1478 - 1482 |
A study of the electrochemical processes in lithium-sulphur cells by impedance spectroscopy
Kolosnitsyn VS, Kuzmina EV, Karaseva EV, Mochalov SE |
| 1483 - 1487 |
Allyl-substituted triazines as additives for enhancing the thermal stability of Li-ion batteries
Cho YH, Kim K, Ahn S, Liu HK |
| 1488 - 1493 |
Highly crystalline lithium-manganese spinel prepared by a hydrothermal process with co-solvent
Lee JW, Kim JI, Min SH |
| 1494 - 1497 |
Electrochemical behavior of Li3-xM' xV2-yM''(y)(PO4)(3) (M' = K, M'' = Sc, Mg plus Ti)/C composite cathode material for lithium-ion batteries
Mateyshina YG, Uvarov NF |
| 1498 - 1502 |
Primary Li-air cell development
Crowther O, Meyer B, Morgan M, Salomon M |
| 1503 - 1507 |
Characteristics and structural change of layered polysilane (Si6H6) anode for lithium ion batteries
Kumai Y, Shirai S, Sudo E, Seki J, Okamoto H, Sugiyama Y, Nakano H |
| 1508 - 1512 |
Surface potential measurement of aged Li-ion batteries using Kelvin probe microscopy
Nagpure SC, Bhushan B, Babu SS |
| 1513 - 1520 |
Cycling degradation of an automotive LiFePO4 lithium-ion battery
Zhang YC, Wang CY, Tang XD |
| 1521 - 1529 |
Optimal arrangement for through-holes in a three-dimensional thin-film battery
Averbuch A, Nathan M, Sedelnikov I |
| 1530 - 1536 |
Fused ring and linking groups effect on overcharge protection for lithium-ion batteries
Wang W, Zhang ZC, Redfern PC, Curtiss LA, Amine K |
| 1537 - 1540 |
High-energy electrode investigation for plug-in hybrid electric vehicles
Lu WQ, Jansen A, Dees D, Nelson P, Veselka NR, Henriksen G |
| 1541 - 1554 |
Lead-acid batteries in micro-hybrid applications. Part I. Selected key parameters
Schaeck S, Stoermer AO, Kaiser F, Koehler L, Albers J, Kabza H |
| 1555 - 1560 |
Lead-acid batteries in micro-hybrid applications. Part II. Test proposal
Schaeck S, Stoermer AO, Albers J, Weirather-Koestner D, Kabza H |
| 1561 - 1568 |
Comparative study on the structure and electrochemical hydriding properties of MgTi, Mg0.5Ni0.5Ti and MgTi0.5Ni0.5 alloys prepared by high energy ball milling
Rousselot S, Guay D, Roue L |
| 1569 - 1577 |
Structural transformation and its effects on the electrochemical performances of a layered double hydroxide
Hu M, Yang ZY, Lei LX, Sun YM |
| 1578 - 1585 |
Simulation of the self-discharge process in vanadium redox flow battery
You DJ, Zhang HM, Sun CX, Ma XK |
| 1586 - 1588 |
Electrochemical co-deposition of magnesium with lithium from quaternary ammonium-based ionic liquid
Shimamura O, Yoshimoto N, Matsumoto M, Egashia M, Morita M |
| 1589 - 1592 |
Influence of zinc ions in electrolytes on the stability of nickel oxide electrodes for single flow zinc-nickel batteries
Cheng J, Wen YH, Cao GP, Yang YS |
| 1593 - 1598 |
Resource constraints on the battery energy storage potential for grid and transportation applications
Wadia C, Albertus P, Srinivasan V |
| 1599 - 1607 |
A reference governer-based hierarchical control for failure mode power management of hybrid power systems for all-electric ships
Seenumani G, Peng H, Sun J |
| 1608 - 1614 |
Syntheses of polyaniline/ordered mesoporous carbon composites with interpenetrating framework and their electrochemical capacitive performance in alkaline solution
Dou YQ, Zhai YP, Liu HJ, Xia YY, Tu B, Zhao DY, Liu XX |
| 1615 - 1619 |
Hierarchical porous carbons prepared by an easy one-step carbonization and activation of phenol-formaldehyde resins with high performance for supercapacitors
Zheng ZJ, Gao QM |
| 1620 - 1625 |
Spark plasma sintered carbon electrodes for electrical double layer capacitor applications
Daffos B, Chevallier G, Estournes C, Simon P |
| 1626 - 1631 |
Polyfluorinated boron cluster based slats: A new electrolyte for application in nonaqueous asymmetric AC/Li4Ti5O12 supercapacitors
Ionica-Bousquet CM, Munoz-Rojas D, Casteel WJ, Pearlstein RM, Kumar GG, Pez GP, Palacin MR |
| 1632 - 1638 |
Enhanced performance of dye-sensitized solar cell with thermally-treated TiN in its TiO2 film prepared at low temperature
Lee CP, Lin LY, Tsai KW, Vittal R, Ho KC |
| 1639 - 1644 |
Electrospraying tuned photoanode structures for dye-sensitized solar cells with enhanced energy conversion efficiency
Li XD, Zhang YZ, Zhang ZX, Zhou JY, Song J, Lu BA, Xie EQ, Lan W |
| 1645 - 1650 |
Balance between the physical diffusion and the exchange reaction on binary ionic liquid electrolyte for dye-sensitized solar cells
Hao F, Lin H, Zhang J, Li JB |
| 1651 - 1656 |
Co-existence of LiI and KI in filler-free, quasi-solid-state electrolyte for efficient and stable dye-sensitized solar cell
Agarwala S, Thummalakunta LNSA, Cook CA, Peh CKN, Wong ASW, Ke L, Ho GW |
| 1657 - 1664 |
Efficient dye-sensitized solar cells with triarylamine organic dyes featuring functionalized-truxene unit
Liang M, Lu M, Wang QL, Chen WY, Han HY, Sun Z, Xue S |
| 1665 - 1670 |
Favorable effects of titanium nitride or its thermally treated version in a gel electrolyte for a quasi-solid-state dye-sensitized solar cell
Lee CP, Lin LY, Vittal R, Ho KC |
| 1671 - 1676 |
Improving the durability of dye-sensitized solar cells through back illumination
Lin LY, Lee CP, Vittal R, Ho KC |
