| 749 - 749 |
Selected papers presented at the International Power Sources Symposium 2005 - Preface
Ware G |
| 750 - 756 |
The development of a carbon-air semi fuel cell
Pointon K, Lakeman B, Irvine J, Bradley J, Jain S |
| 757 - 764 |
Control analysis of renewable energy system with hydrogen storage for residential applications
Bilodeau A, Agbossou K |
| 765 - 772 |
The direct borohydride fuel cell for UUV propulsion power
Lakernan JB, Rose A, Pointon KD, Browning DJ, Lovell KV, Waring SC, Horsfall JA |
| 773 - 779 |
Advanced manganese oxide material for rechargeable lithium cells
Atwater TB, Salkind AJ |
| 780 - 789 |
Studies of cycling behavior, ageing, and interfacial reactions of LiNi0.5Mn1.5O4 and carbon electrodes for lithium-ion 5-V cells
Aurbach D, Markovsky B, Talyossef Y, Salitra G, Kim HJ, Choi S |
| 790 - 796 |
Recent developments in Li-ion prismatic cells
Cousseau JF, Siret C, Biensan P, Broussely M |
| 797 - 799 |
Organic polymer gel electrolyte for Li-ion batteries
Basumallick I, Roy P, Chatterjee A, Bhattacharya A, Chatterjee S, Ghosh S |
| 800 - 802 |
A prelithiated carbon anode for lithium-ion battery applications
Jarvis CR, Lain MJ, Yakovleva MV, Gao Y |
| 803 - 808 |
Low temperature synthesis and characterization of nanoscale CU6Sn5 particles as lithium anode material
Mladenov M, Zlatilova P, Dragieva I, Klabunde K |
| 809 - 812 |
Recent developments and likely advances in lithium-ion batteries
Ritchie A, Howard W |
| 813 - 817 |
Mechanism of Li-doping into Li4Ti5O12 negative active material for Li-ion cells by new chemical method
Tabuchi T, Yasuda H, Yamachi M |
| 818 - 822 |
Separator-free rechargeable lithium ion cells produced by the extrusion lamination of polymer gel electrolytes
Ward IM, Hubbard HVSA, Wellings SC, Thompson GP, Kaschmitter J, Wang H |
| 823 - 828 |
Coating technique for improvement of the cycling stability of LiCo/NiO2 electrode materials
Zhecheva E, Mladenov M, Stoyanova R, Vassilev S |
| 829 - 836 |
Design and implementation of a fuzzy logic-based state-of-charge meter for Li-ion batteries used in portable defibrillators
Singh P, Vinjamuri R, Wang XQ, Reisner D |
| 837 - 840 |
Hybrid cathode lithium batteries for implantable medical applications
Chen K, Merritt DR, Howard WG, Schmidt CL, Skarstad PA |
| 841 - 846 |
Development of high energy density small flat spiral cells and battery pack based on lithium/carbon monofluoride (Li/CFx)
Eweka EI, Giwa CO, Mepsted GO, Green K, Scattergood D |
| 847 - 850 |
Improved performance of Li hybrid solid polymer electrolyte cells
Nagasubramanian G, Bronstein L, Carini J |
| 851 - 863 |
Studies on electrolyte formulations to improve life of lead acid batteries working under partial state of charge conditions
Hernandez JC, Soria ML, Gonzalez M, Garcia-Quismondo E, Munoz A, Trinidad F |
| 864 - 869 |
Influence of temperature and electrolyte saturation on rate and efficiency of oxygen cycle in VRLAB
Kirchev A, Pavlov D |
| 870 - 877 |
State-of-charge determination of lead-acid batteries using wire-wound coils
Hill IR, Andrukaitis EE |
| 878 - 883 |
Application of pulse charging techniques to submarine lead-acid batteries
James M, Grummett J, Rowan M, Newman J |
| 884 - 892 |
ABLE project: Development of an advanced lead-acid storage system for autonomous PV installations
Lemaire-Potteau E, Vallve X, Pavlov D, Papazov G, Van der Borg N, Sarrau JF |
| 893 - 899 |
Performance improvements of alkaline batteries by studying the effects of different kinds of surfactant and different derivatives of benzene on the electrochemical properties of electrolytic zinc
Ghavami RK, Rafiei Z |
| 900 - 905 |
Pulse power 350 V nickel-metal hydride battery power-D-005-00181
Eskra MD, Ralston P, Salkind A, Plivelich RE |
| 906 - 912 |
Modelling a reliable wind/PV/storage power system for remote radio base station sites without utility power
Bitterlin IF |
| 913 - 919 |
SUBAT: An assessment of sustainable battery technology
Van den Bossche P, Vergels F, Van Mierlo J, Matheys J, Autenboer W |
| 920 - 926 |
Battery testing by calculated discharge-curve method - Constant resistive load algorithm
Djordjevic AB, Karanovic DM |
| 927 - 934 |
Power sources compared: The ultimate truth?
Flipsen SFJ |
| 935 - 942 |
Power sources for autonomous underwater vehicles
Hasvold O, Storkersen NJ, Forseth S, Lian T |
| 943 - 948 |
A probabilistic method for calculating the usefulness of a store with finite energy capacity for smoothing electricity generation from wind and solar power
Barton JP, Infield DG |
| 949 - 953 |
Value of storage in providing balancing services for electricity generation systems with high wind penetration
Black M, Strbac G |
| 954 - 958 |
Towards a more efficient energy use in photovoltaic powered products
Kan SY, Strijk R |
| 959 - 964 |
Integrating energy storage with wind power in weak electricity grids
McDowall J |
| 965 - 970 |
Hybrid power supplies: A capacitor-assisted battery
Catherino HA, Burgel JF, Shi PL, Rusek A, Zou XL |
| 971 - 974 |
The use of battery-capacitor combinations in photovoltaic powered products
Kan SY, Verwaal M, Broekhuizen H |
| 977 - 984 |
Photographic production of metal nano-particles for fuel cell electrodes
Jiang J, Hall TD, Tsagalas L, Hill DA, Miller AE |
| 985 - 991 |
An investigation of convective transport in micro proton-exchange membrane fuel cells
Rawool AS, Mitra SK, Pharoah JG |
| 992 - 1002 |
Three-dimensional, two-phase, CFD model for the design of a direct methanol fuel cell
Danilov VA, Lim J, Moon I, Chang H |
| 1003 - 1009 |
Block sulfonated poly(ether ether ketone)s (SPEEK) ionomers with high ion-exchange capacities for proton exchange membranes
Zhao CJ, Lin HD, Shao K, Li XF, Ni HZ, Wang Z, Na H |
| 1010 - 1022 |
Electrochemical impedance spectroscopy study of methanol oxidation on nanoparticulate PtRu direct methanol fuel cell anodes: Kinetics and performance evaluation
Chakraborty D, Chorkendoff I, Johannessen T |
| 1023 - 1028 |
Modification of carbon support to enhance performance of direct methanol fuel cell
Park CH, Scibioh MA, Kim HJ, Oh IH, Hong SA, Ha HY |
| 1029 - 1035 |
Gas distribution in molten-carbonate fuel cells
Okada T, Matsumoto S, Matsumura M, Miyazaki M, Umeda M |
| 1036 - 1042 |
Anode-supported solid oxide fuel cell with yttria-stabilized zirconia/gadolinia-doped ceria bilalyer electrolyte prepared by wet ceramic co-sintering process
Liu QL, Khor KA, Chan SH, Chen XJ |
| 1043 - 1052 |
Oxygen reduction on strontium-doped LaMnO3 cathodes in the absence and presence of an iron-chromium alloy interconnect
Zhen YD, Li J, Jiang SP |
| 1053 - 1059 |
Yttria-stabilized zirconia thin films deposited on NiO-(Sm2O3)(0.1) (CeO2)(0.8) substrates by chemical vapor infiltration
Kikuchi K, Tamazaki F, Okada K, Mineshige A |
| 1060 - 1066 |
Growth mechanism of thin films of yttria-stabilized zirconia by chemical vapor infiltration using NiO-ceria substrate as oxygen source
Kikuchi K, Okada K, Mineshige A |
| 1067 - 1072 |
High performance rare earth oxides LnO(x) (Ln = Sc, Y, La, Ce, Pr and Nd) modified Pt/C electrocatalysts for methanol electrooxidation
Tang ZC, Lu GX |
| 1073 - 1076 |
A 28-W portable direct borohydride-hydrogen peroxide fuel-cell stack
Raman RK, Prashant SK, Shukla AK |
| 1077 - 1081 |
Vanadium oxide nanotubes as the support of Pd catalysts for methanol oxidation in alkaline solution
Zhang KF, Guo DJ, Liu X, Li J, Li HL, Su ZX |
| 1082 - 1087 |
Polyvinyl alcohol-induced low temperature synthesis of CeO2-based powders
Ma JJ, Jiang CR, Zhou XL, Meng GY, Liu XQ |
| 1088 - 1093 |
Novel application of aluminum salt for cost-effective fabrication of a highly creep-resistant nickel-aluminum anode for a molten carbonate fuel cell
Lee H, Lee I, Lee D, Lim H |
| 1094 - 1098 |
Electrocatalytic oxidation of formaldehyde on palladium nanoparticles supported on multi-walled carbon nanotubes
Gao GY, Guo DJ, Li HL |
| 1099 - 1103 |
Development of ruthenium-based bimetallic electrocatalysts for oxygen reduction reaction
Liu LY, Lee JW, Popov BN |
| 1104 - 1114 |
The dynamic behavior of pressure during purge process in the anode of a PEM fuel cell
Gou J, Pei PC, Wang Y |
| 1115 - 1121 |
A methanol concentration sensor using twin membrane electrode assemblies operated in pulsed mode for DMFC
Sun W, Sun GQ, Yang WQ, Yang SH, Xin Q |
| 1122 - 1129 |
Evaluating the enhanced performance of a novel wave-like form gas flow channel in the PEMFC using the field synergy principle
Kuo JK, Chen CK |
| 1130 - 1136 |
Water transport in the proton exchange-membrane fuel cell: Comparison of model computation and measurements of effective drag
Murahashi T, Naiki M, Nishiyama E |
| 1137 - 1146 |
Theoretical approaches to studying the single and simultaneous reactions in laminar flow-based membraneless fuel cells?
Chen WY, Chen FL |
| 1147 - 1156 |
Transient analysis of water transport in PEM fuel cells
Yan WM, Chu HS, Chen JY, Soong CY, Chen FL |
| 1157 - 1164 |
Effects of operating conditions on cell performance of PEM fuel cells with conventional or interdigitated flow field
Yan WM, Chen CY, Mei SC, Soong CY, Chen FL |
| 1165 - 1171 |
Estimation of contact resistance in proton exchange membrane fuel cells
Zhang LH, Liu Y, Song HM, Wang SX, Zhou YY, Hu SJ |
| 1172 - 1181 |
Performance of Ni/ScSZ cermet anode modified by coating with Gd0.2Ce0.8O2 for an SOFC running on methane fuel
Huang B, Ye XF, Wang SR, Nie HW, Shi J, Hu Q, Qian JQ, Sun XF, Wen TL |
| 1182 - 1191 |
Numerical simulation of proton exchange membrane fuel cells at high operating temperature
Peng J, Lee SJ |
| 1192 - 1202 |
CFD analysis of a solid oxide fuel cell with internal reforming: Coupled interactions of transport, heterogeneous catalysis and electrochemical processes
Janardhanan VM, Deutschmann O |
| 1203 - 1212 |
Comparison of temperature distributions inside a PEM fuel cell with parallel and interdigitated gas distributors
Hwang JJ, Liu SJ |
| 1213 - 1219 |
A strategy for the spatial temperature control of a molten carbonate fuel cell system
Sheng M, Mangold M, Kienle A |
| 1220 - 1225 |
Nonlinear modeling of a SOFC stack based on a least squares support vector machine
Huo HB, Zhu XH, Cao GY |
| 1226 - 1231 |
Experimental characterization of in-plane permeability of gas diffusion layers
Feser JP, Prasad AK, Advani SG |
| 1232 - 1235 |
Passive direct methanol fuel cells fed with methanol vapor
Kim H |
| 1236 - 1240 |
Heat balance in the catalyst layer and the boundary condition for heat transport equation in a low-temperature fuel cell
Kulikovsky AA |
| 1241 - 1253 |
Life cycle comparison of fuel cell vehicles and internal combustion engine vehicles for Canada and the United States
Zamel N, Li XG |
| 1254 - 1264 |
Integrated fuel processor built on autothermal reforming of gasoline: A proof-of-principle study
Qi AD, Wang SD, Fu GZ, Wu DY |
| 1265 - 1269 |
A 75-kW methanol reforming fuel cell system
Yan XQ, Wang SD, Li XY, Hou M, Yuan ZS, Li DY, Pan LW, Zhang C, Liu JK, Ming PW, Yi BL |
| 1270 - 1274 |
Hydrogen production by auto-thermal reforming of ethanol over Ni/-gamma-Al2O3 catalysts: Effect of second metal addition
Youn MH, Seo JG, Kim P, Kim JJ, Lee HI, Song IK |
| 1275 - 1281 |
Carbon nanotubes (CNTs) as a buffer layer in silicon/CNTs composite electrodes for lithium secondary batteries
Kim T, Mo YH, Nahm KS, Oh SM |
| 1282 - 1288 |
Thermal reactions of mesocarbon microbead (MCMB) particles in LiPF6-based electrolyte
Xiao A, Li WT, Lucht BL |
| 1289 - 1296 |
Kinetic behavior of LiFeMgPO4 cathode material for Li-ion batteries
Hong J, Wang CS, Kasavajjula U |
| 1297 - 1303 |
Influence of glyme-based nonaqueous electrolyte solutions on electrochemical properties of Si-based anodes for rechargeable lithium cells
Inose T, Watanabe D, Morimoto H, Tobishima SI |
| 1304 - 1311 |
Effects of addition of TiO2 nanoparticles on mechanical properties and ionic conductivity of solvent-free polymer electrolytes based on porous P(VdF-HFP)/P(EO-EC) membranes
Jeon JD, Kim MJ, Kwak SY |
| 1312 - 1321 |
Metal oxyfluorides TiOF2 and NbO2F as anodes for Li-ion batteries
Reddy MV, Madhavi S, Rao GVS, Chowdari BVR |
| 1322 - 1328 |
Properties of a novel hard-carbon optimized to large size Li ion secondary battery studied by Li-7 NMR
Gotoh K, Maeda M, Nagai A, Goto A, Tansho M, Hashi K, Shimizu T, Ishida H |
| 1329 - 1335 |
In situ XAFS and micro-XAFS studies on LiNi0.8Co0.15Al0.05O2 cathode material for lithium-ion batteries
Nonaka T, Okuda C, Seno Y, Nakano H, Koumoto K, Ukyo Y |
| 1336 - 1340 |
A relation between enhanced Li ion transfer and the improvement in electrochemical performance of a Si-Cu-carbon composite
Kang YM, Park MS, Song MS, Lee JY |
| 1341 - 1345 |
Phase separation and electrical conductivity of lithium borosilicate glasses for potential thin film solid electrolytes
Lee SH, Cho KI, Choi JB, Shin DW |
| 1346 - 1350 |
High capacity Li[Li0.2Ni0.2Mn0.6]O-2 cathode materials via a carbonate co-precipitation method
Lee DK, Park SH, Amine K, Bang HJ, Parakash J, Sun YK |
| 1351 - 1356 |
Influence of the microstructure on the electrochemical performance of thin film WO3 cathode
Figueroa R, Kleinke M, Cruz TGS, Gorenstein A |
| 1357 - 1362 |
Preparation and electrochemical studies of Fe-doped Li3V2(PO4)(3) cathode materials for lithium-ion batteries
Ren MM, Zhou Z, Li YZ, Gao XP, Yan J |
| 1363 - 1366 |
Enhancing the thermal stability of LiCoO2 electrode by 4-isopropyl phenyl diphenyl phosphate in lithium ion batteries
Wang QS, Sun JH, Chen CH |
| 1367 - 1372 |
Synthesis and electrochemical properties of Mo-doped Li[Ni1/3Mn1/3Co1/3]O-2 cathode materials for Li-ion battery
Wang LQ, Hao LF, Yuan HT, Guo J, Zhao M, Li HX, Wang YM |
| 1373 - 1378 |
The electrochemistry of nanostructured In2O3 with lithium
Zhou YN, Zhang H, Xue MZ, Wu CL, Wu XJ, Fu ZW |
| 1379 - 1394 |
A review on electrolyte additives for lithium-ion batteries
Zhang SS |
| 1395 - 1400 |
Simulation of charge-discharge cycling of lithium-ion batteries under low-earth-orbit conditions
Lee JW, Anguchamy YK, Popov BN |
| 1401 - 1408 |
Ionic liquids containing the tetrafluoroborate anion have the best performance and stability for electric double layer capacitor applications
Yuyama K, Masuda G, Yoshida H, Sato T |
| 1409 - 1415 |
A microbial fuel cell using permanganate as the cathodic electron acceptor
You SJ, Zhao QL, Zhang JN, Jiang JQ, Zhao SQ |
| 1416 - 1420 |
Characteristics and performance of 10 kW class all-vanadium redox-flow battery stack
Zhao P, Zhang HM, Zhou HT, Chen J, Gao SJ, Yi BL |
| 1421 - 1430 |
Miniaturized g- and spin-activated Pb/HBF4/PbO2 reserve batteries as power sources for electronic fuzes
Yoon SH, Son JT, Oh JS |
| 1431 - 1436 |
Reduction of CO2 concentration in a zinc/air battery by absorption in a rotating packed bed
Cheng HH, Tan CS |
| 1437 - 1443 |
Electrochemical characterization on MnFe2O4/carbon black composite aqueous supercapacitors
Kuo SL, Wu NL |
| 1444 - 1450 |
Application of 1-ethyl-3-methylimidazolium thiocyanate to the electrolyte of electrochemical double layer capacitors
Sun GH, Li KX, Sun CG |
| 1451 - 1454 |
Synthesis of vanadium pentoxide powders with enhanced surface-area for electrochemical capacitors
Lao ZJ, Konstantinov K, Tournaire Y, Ng SH, Wang GX, Liu HK |
| 1455 - 1459 |
Triethanolamine as an additive of high water content electrolyte to enhance the capacitor's performance
Wang KL, Chang RF |
| 1460 - 1466 |
The advanced carbide-derived carbon based supercapacitor
Arulepp M, Leis J, Latt M, Miller F, Rumma K, Lust E, Burke AF |
| 1467 - 1470 |
Flexible micro-supercapacitors
Sung JH, Kim SJ, Jeong SH, Kim EH, Lee KH |
