| 1 - 9 |
Electrochemical properties of lanthanum strontium aluminum ferrites for the oxygen reduction reaction
Coffey GW, Hardy J, Pedersen LR, Rieke PC, Thomsen EC, Walpole M |
| 11 - 16 |
Operation of anode-supported solid oxide fuel cells on methane and natural gas
Liu JA, Barnett SA |
| 17 - 28 |
Oxygen electrode reaction on Nd2NiO4+delta cathode materials: impedance spectroscopy study
Mauvy F, Bassat JM, Boehm E, Manaud JP, Dordor P, Grenier JC |
| 29 - 43 |
A simple bilayer electrolyte model for solid oxide fuel cells
Chan SH, Chen XJ, Khor KA |
| 45 - 53 |
Observation of structural change induced by cathodic polarization on (La,Sr)MnO3 electrodes of solid oxide fuel cells
Jiang SP, Love JG |
| 55 - 65 |
Ln(1-x)Sr(x)Co(1-y)Fe(y)O(3-delta) (Ln=Pr, Nd, Gd; x=0.2, 0.3) for the electrodes of solid oxide fuel cells
Qiu L, Ichikawa T, Hirano A, Imanishi N, Takeda Y |
| 67 - 77 |
Oxygen exchange and diffusion in the near surface of pure and modified yttria-stabilised zirconia
de Ridder M, van Welzenis RG, Brongersma HH, Kreissig U |
| 79 - 90 |
Compatibility of GdxTi2O7 pyrochlores (1.72 <= x <= 2.0) as electrolytes in high-temperature solid oxide fuel cells
Mori M, Tompsett GM, Sammes NM, Suda E, Takeda Y |
| 91 - 102 |
Structural and electrochemical properties of LiCoO2 prepared by combustion synthesis
Santiago EI, Andrade AVC, Paiva-Santos CO, Bulhoes LOS |
| 103 - 111 |
Electrochemical properties of LiCoyMn2-yO4 synthesized by the combustion method for lithium secondary battery
Kwon I, Song MY |
| 113 - 117 |
Low-temperature hydrothermal synthesis of spinel-type lithium manganese oxide nanocrystallites
Zhang YC, Wang H, Xu HY, Wang B, Yan H, Ahniyaz A, Yoshimura M |
| 119 - 132 |
Anomalies in Li+ ion dynamics observed by impedance spectroscopy and Li-7 NMR in the perovskite fast ion conductor (Li3xLa2/3-x square(1/3-2x))TiO3
Bohnke O, Emery J, Fourquet JL |
| 133 - 139 |
Preparations of perovskite-type oxides LaCoO3 from three different methods and their evaluation by homogeneity, sinterability and conductivity
Nakayama S, Okazaki M, Aung YL, Sakamoto M |
| 141 - 150 |
Oxides of the AMO(3) and A(2)MO(4)-type: structural stability, electrical conductivity and thermal expansion
Al Daroukh M, Vashook VV, Ullmann H, Tietz F, Raj IA |
| 151 - 156 |
Formation and ionic conductivity of Li2S-GeS2-Ga2S3 glasses and thin films
Yamashita M, Yamanaka H |
| 157 - 166 |
Structure and ionic conductivity of the lacunary apatite Pb6Ca2Na2(PO4)(6)
Naddari T, El Feki H, Savariault JM, Salles P, Ben Salah A |
| 167 - 175 |
Electronic structure of Ag2S, band calculation and photoelectron spectroscopy
Kashida S, Watanabe N, Hasegawa T, Iida H, Mori M, Savrasov S |
| 177 - 186 |
Thermal analysis of a solid polymer electrolyte and a subsequent electrochemical investigation of a lithium polymer battery
Edman L, Doeff MM |
| 187 - 197 |
Study of sol-gel prepared nanostructured WO3 thin films and composites for electrochromic applications
Badilescu S, Ashrit PV |
| 199 - 204 |
Microwave processing of sodium beta alumina
Subasri R, Mathews T, Sreedharan OM, Raghunathan VS |
| 205 - 209 |
New poly[bis-(methoxyethoxyethoxy)phosphazene]-MoS2 nanocomposite
Bissessur R, Gallant D, Bruning R |
