| 1271 - 1291 |
A review on air cathodes for zinc-air fuel cells
Neburchilov V, Wang HJ, Martin JJ, Qu W |
| 1292 - 1301 |
Minimization of the cation mixing in Li1-x(NMC)(1-x)O-2 as cathode material
Zhang XY, Jiang WJ, Mauger A, Qilu, Gendron F, Julien CM |
| 1302 - 1307 |
Numerical determination of the effective thermal conductivity of fibrous materials. Application to proton exchange membrane fuel cell gas diffusion layers
Veyret D, Tsotridis G |
| 1308 - 1315 |
Synthesis of nanocomposite nickel oxide/yttrium-stabilized zirconia (NiO/YSZ) powders for anodes of solid oxide fuel cells (SOFCs) via microwave-assisted complex-gel auto-combustion
Cai TX, Zeng YW, Zhang W, Guo CJ, Yang XW |
| 1316 - 1324 |
Effect of various coal gas contaminants on the performance of solid oxide fuel cells: Part III. Synergistic effects
Bao JE, Krishnan GN, Jayaweera P, Sanjurjo A |
| 1325 - 1332 |
Preparation of high-performance polymer electrolyte nanocomposites through nanoscale silica particle dispersion
Lee CH, Park HB, Park CH, Lee SY, Kim JY, McGrath JE, Lee YM |
| 1333 - 1343 |
Assessment of nickel cermets and La0.8Sr0.2Sc0.2Mn0.8O3 as solid-oxide fuel cell anodes operating on carbon monoxide fuel
Su C, Wu YZ, Wang W, Zheng Y, Ran R, Shao ZP |
| 1344 - 1351 |
Carbon deposition on Ni/YSZ anodes exposed to CO/H-2 feeds
Alzate-Restrepo V, Hill JM |
| 1352 - 1358 |
Improved performance of PtRu/C prepared by selective deposition of Ru on Pt as an anode for a polymer electrolyte membrane fuel cell
Kim HT, Joh HI, Moon SH |
| 1359 - 1364 |
Ni-LnO(x) (Ln = La, Ce, Pr, Nd, Sm, Eu, and Gd) cermet anodes for intermediate-temperature solid oxide fuel cells
He BB, Ding D, Xia CR |
| 1365 - 1369 |
Titanium carbide nanoparticles supported Pt catalysts for methanol electrooxidation in acidic media
Ou YW, Cui XL, Zhang XY, Jiang ZY |
| 1370 - 1374 |
Carbon-supported manganese oxide nanocatalysts for rechargeable lithium-air batteries
Cheng H, Scott K |
| 1375 - 1378 |
An in situ Fourier transform infrared spectroelectrochemical study on ethanol electrooxidation on Pd in alkaline solution
Fang X, Wang LQ, Shen PK, Cui GF, Bianchini C |
| 1379 - 1382 |
In situ Fenton-enhanced cathodic reaction for sustainable increased electricity generation in microbial fuel cells
Zhuang L, Zhou SG, Li YT, Liu TL, Huang DY |
| 1383 - 1392 |
A high efficient assembly technique for large proton exchange membrane fuel cell stacks: Part II. Applications
Lin P, Zhou P, Wu CW |
| 1393 - 1400 |
Experimental study of a novel piezoelectric proton exchange membrane fuel cell with nozzle and diffuser
Ma HK, Huang SH, Wang JS, Hou CG, Yu CC, Chen BR |
| 1401 - 1407 |
Ex situ evaluation of nanometer range gold coating on stainless steel substrate for automotive polymer electrolyte membrane fuel cell bipolar plate
Kumar A, Ricketts M, Hirano S |
| 1408 - 1415 |
Liquid water transport mechanism in the gas diffusion layer
Zhou P, Wu CW |
| 1416 - 1426 |
The empirical validation of a model for simulating the thermal and electrical performance of fuel cell micro-cogeneration devices
Beausoleil-Morrison I |
| 1427 - 1434 |
Fuel sensor-less control of a liquid feed fuel cell under dynamic loading conditions for portable power sources (II)
Chang CL, Chen CY, Sung CC, Liou DH, Chang CY, Cha HC |
| 1435 - 1440 |
Design for segmented-in-series solid oxide fuel cell through mathematical modeling
Cui DA, Cheng MJ |
| 1441 - 1445 |
Rational design of novel cathode materials in solid oxide fuel cells using first-principles simulations
Choi YM, Lin MC, Liu ML |
| 1446 - 1453 |
Effects of fuel processing methods on industrial scale biogas-fuelled solid oxide fuel cell system for operating in wastewater treatment plants
Farhad S, Yoo Y, Hamdullahpur F |
| 1454 - 1462 |
Experimental investigation of 1 kW solid oxide fuel cell system with a natural gas reformer and an exhaust gas burner
Yen TH, Hong WT, Huang WP, Tsai YC, Wang HY, Huang CN, Lee CH |
| 1463 - 1471 |
Chemical vapor synthesis and characterization of aluminum nanopowder
Choi JW, Sohn HY, Choi YJ, Fang ZGZ |
| 1472 - 1478 |
High-throughput quantum chemistry and virtual screening for lithium ion battery electrolyte additives
Halls MD, Tasaki K |
| 1479 - 1485 |
Polyfluorinated boron cluster-based salts: A new electrolyte for application in Li4Ti5O12/LiMn2O4 rechargeable lithium-ion batteries
Ionica-Bousquet CM, Munoz-Rojas D, Casteel WJ, Pearlstein RM, GirishKumar G, Pez GP, Palacin MR |
| 1486 - 1494 |
Preparation of spherical LiNi0.80Co0.15Mn0.05O2 lithium-ion cathode material by continuous co-precipitation
Cheralathan KK, Kang NY, Park HS, Lee YJ, Choi WC, Ko YS, Park YK |
| 1495 - 1499 |
Imidazolium ionic liquids containing LiBOB electrolyte for lithium battery
Saruwatari H, Kuboki T, Kishi T, Mikoshiba S, Takami N |
| 1500 - 1509 |
The effect of communication architecture on the availability, reliability, and economics of plug-in hybrid electric vehicle-to-grid ancillary services
Quinn C, Zimmerle D, Bradley TH |
| 1510 - 1515 |
On the LiNi0.2Mn0.2Co0.6O2 positive electrode material
Bentaleb Y, Saadoune I, Maher K, Saadi L, Fujimoto K, Ito S |
| 1516 - 1521 |
A doped activated carbon prepared from polyaniline for high performance supercapacitors
Li LM, Liu EH, Li J, Yang YJ, Shen HJ, Huang ZZ, Xiang XX, Li W |
| 1522 - 1528 |
Facile synthesis and electrochemical properties of conducting SrRuO3-RuO2 composite nanofibre mats
Hyun TS, Kim HG, Kim ID |
