| 2201 - 2204 |
Monolithic electrochemically promoted reactors: A step for the practical utilization of electrochemical promotion
Balomenou SP, Tsiplakides D, Katsaounis A, Brosda S, Hammad A, Foti G, Comninellis C, Thiemann-Handler S, Cramer B, Vayenas CG |
| 2205 - 2209 |
Non-faradaic electrochemical modification of the catalytic activity for propane combustion of Pt/YSZ and Rh/YSZ catalyst-electrodes
Bebelis S, Kotsionopoulos N |
| 2211 - 2215 |
Electrochemical promotion of a metal catalyst supported on a mixed-ionic conductor
Poulidi D, Metcalfe IS |
| 2217 - 2220 |
NH3 decomposition in a single-chamber proton conducting cell
Skodra A, Ouzounidou M, Stoukides M |
| 2221 - 2225 |
STM observation of the origin of electrochemical promotion on metal catalyst-electrodes interfaced with YSZ and beta''-Al2O3
Archonta D, Frantzis A, Tsiplakides D, Vayenas CG |
| 2227 - 2233 |
Transport properties and phase stability of mixed conducting oxide membranes
Park CY, Huang DX, Jacobson AJ, Hu L, Mims CA |
| 2235 - 2239 |
O- emission from 12CaO center dot 7Al(2)O(3) and MSZ composite and its application for silicon oxidation
Nishioka M, Nanjyo H, Hamakawa S, Kobayashi K, Sato K, Inoue T, Mizukami F, Sadakata M |
| 2241 - 2244 |
BIMEVOX as dense membrane in catalytic reactor (ME = Co, Cu, Ta)
Pirovano C, Lofberg A, Bodet H, Bordes-Richard E, Steil MC, Vannier RN |
| 2245 - 2248 |
Fe-based perovskite-type oxides as excellent oxygen-permeable and reduction-tolerant materials
Teraoka Y, Shimokawa H, Kang CY, Kusaba H, Sasaki K |
| 2249 - 2253 |
Surface effect on oxygen permeation through dense membrane of mixed-conductive LSCF perovskite-type oxide
Kusaba H, Shibata Y, Sasaki K, Teraoka Y |
| 2255 - 2259 |
Mixed oxygen ion and electron conducting hollow fiber membranes for oxygen separation
Wang H, Schiestel T, Tablet C, Schroeder M, Caro J |
| 2261 - 2267 |
Oxygen permeation characteristics of zirconia with surface modification
Park HJ, Choi GM |
| 2269 - 2273 |
Conductivity and oxygen permeability of a novel oxide Pr2Ni0.8-xCu0.2FexO4 and its application to partial oxidation of CH4
Miyoshi S, Furuno T, Matsumoto H, Ishihara T |
| 2275 - 2279 |
Synthesis and characterization of the double-substituted perovskites LaxSr1-xCo1-yMnyO3-delta for use in high-temperature oxygen separations
Ambrosini A, Garino T, Nenoff TM |
| 2281 - 2284 |
Oxygen permeation properties and the stability of La0.6Sr0.4Fe0.8Co0.2O3 studied by Raman spectroscopy
Iguchi F, Sata N, Yugami H, Takamura H |
| 2285 - 2289 |
Mixed conductivity and electrocatalytic performance of SrFeO3-delta-SrAl2O4 composite membranes
Yaremchenko AA, Kharton VV, Valente AA, Shaula AL, Marques FMB, Rocha J |
| 2291 - 2296 |
Engines and exhaust after treatment systems for future automotive applications
Alkemade UG, Schumann B |
| 2297 - 2300 |
Simultaneous removal of nitrogen oxides and diesel soot particulate in nano-structured electrochemical reactor
Hamamoto K, Fujishiro Y, Awano M |
| 2301 - 2304 |
Electrode materials for potentiometric hydrogen sensors
Zosel J, Schiffel G, Gerlach F, Ahlborn K, Sasum U, Vashook V, Guth U |
| 2305 - 2311 |
Mixed-potential-type zirconia-based NOx sensor using Rh-loaded NiO sensing electrode operating at high temperatures
Wang J, Elumalai P, Terada D, Hasei M, Miura N |
| 2313 - 2316 |
Sensor application-related defect chemistry and electromechanical properties of langasite
Fritze H, Schulz M, Seh H, Tuller HL |
| 2317 - 2320 |
Fabrication of a highly sensitive sensor electrode using a nano-gapped gold particle film
Tokonami S, Iwamoto M, Hashiba K, Shiigi H, Nagaoka T |
| 2321 - 2323 |
Impedance spectroscopy of Na+ conducting zeolite ZSM-5
Dubbe A, Hagen G, Moos R |
| 2325 - 2328 |
Electrical properties of a nanoparticle-networked film
Yamamoto Y, Yoshi N, Shiigi H, Nagaoka T |
| 2329 - 2332 |
Proton conduction in LaSrScO3 single crystals
Liu J, Chiba Y, Kawamura J, Yugami H |
| 2333 - 2337 |
Pulsed laser deposition of high temperature protonic films
Dynys FW, Berger MH, Sayir A |
| 2339 - 2345 |
Microstructural and electrical characterisation of melt grown high temperature protonic conductors
Berger MH, Sayir A, Dynys F, Berger P |
| 2347 - 2351 |
Structural and electrical properties of SrZr0.95Y0.05O3/SrTiO3 superlattices
Kuwata N, Sata N, Saito S, Tsurui T, Yugami H |
| 2353 - 2356 |
The determination of deuteron site in SrZr0.95Sc0.05O3-alpha by neutron powder diffraction
Ito T, Nagasaki T, Iwasaki K, Yoshino M, Matsui T, Igawa N, Ishii Y |
| 2357 - 2362 |
Proton conductivity and low temperature structure of In-doped BaZrO3
Ahmed I, Eriksson SG, Ahlberg E, Knee CS, Karlsson M, Matic A, Engberg D, Borjesson L |
| 2363 - 2368 |
Chemical diffusion of water in the double perovskites Ba4Ca2Nb2O11 and Sr6Ta2O11
Animitsa I, Neiman A, Kochetova N, Korona D, Sharafutdinov A |
| 2369 - 2373 |
Electrical conduction properties of rare earth orthophosphates under reducing conditions
Kitamura N, Amezawa K, Uchimoto Y, Tomii Y, Hanada T, Yamamoto N |
| 2375 - 2379 |
Dielectric relaxation of protonic defects in hydrated and dehydrated SrZrO3 : Yb
Kamishima O, Abe Y, Ishii T, Kawamura J, Hattori T |
| 2381 - 2384 |
The influence of grain structures on the electrical conductivity of a BaZr0.95Y0.05O3 proton conductor
Iguchi F, Yamada T, Sata N, Tsurui T, Yugami H |
| 2385 - 2390 |
The effects of backbone conformation on hydration and proton transfer in the'short-side-chain' perfluorosulfonic acid membrane
Paddison SJ, Elliott JA |
| 2391 - 2396 |
Zirconium phosphate Nafion (R) composites - a microstructure-based explanation of mechanical and conductivity properties
Bauer F, Willert-Porada M |
| 2397 - 2401 |
Potential-dependent electrolyte resistance and steady-state multiplicities of PEM fuel cells
Katsaounis A, Tsampas M, Balomenou SP, Tsiplakides D, Vayenas CG |
| 2403 - 2406 |
Development of high protonic conductors based on amorphous mesoporous alumina
Shen HY, Maekawa H, Kawamura J, Yamamura T |
| 2407 - 2411 |
High temperature protonic conduction in Sr-doped LaP3O9
Amezawa K, Uchimoto Y, Tomii Y |
| 2413 - 2416 |
Fabrication and characterization of solid state proton conductor (NH4)(2)SiP4O13-NH4PO3 for fuel cells operated at 150-250 degrees C
Chen XL, Huang Z, Xia CR |
| 2417 - 2419 |
NH4PO3/SiO2 composite as electrolyte for intermediate temperature fuel cells
Liu LJ, Tu HY, Cremers C, Stimming U |
| 2421 - 2424 |
Structure and proton conductivity of mechanochemically treated 50CsHSO(4)center dot 50CsH(2)PO(4)
Matsuda A, Kikuchi T, Katagiri K, Muto H, Sakai M |
| 2425 - 2430 |
Proton conducting membranes from sulfonated poly[bis(phenoxy) phosphazenes] with an interpenetrating hydrophilic network
Burjanadze M, Paulsdorf J, Kaskhedikar N, Karatas Y, Wiemhofer HD |
| 2431 - 2435 |
Structural analysis of PVA-based proton conducting membranes
Martinelli A, Matic A, Jacobsson P, Borjesson L, Navarra MA, Fernicola A, Panero S, Scrosati B |
| 2437 - 2441 |
Operation of PEFC using composite sheets composed of phosphosilicate gels and thermally stable organic polymers
Matsuda A, Nakamoto N, Tadanaga K, Minami T, Tatsumisago M |
| 2443 - 2445 |
Raman study on defect structure of high-temperature protonic conducting ceramics
Mineshige A, Okada S, Kobune M, Yazawa T |
| 2447 - 2451 |
Hydration behavior of Ba2Sc2O5 with an oxygen-deficient perovskite structure
Omata T, Fuke T, Otsuka-Yao-Matsuo S |
| 2453 - 2456 |
Protonic conductivity and lithium intercalation in a new iron hydroxyphosphate hydrate: (H3O)[Fe(H2O)](3)[H-8(PO4)(6)] center dot 3H(2)O
Pralong V, Caignaert V, Raveau B |
| 2457 - 2462 |
Intermediate temperature proton conductors based on phosphonic acid functionalized oligosiloxanes
Steininger H, Schuster M, Kreuer KD, Maier J |
| 2463 - 2466 |
Preparation of proton conductive composites with CsHSO4/CsH2PO4 and phosphosilicate gel
Tezuka T, Tadanaga K, Hayashi A, Tatsumisago M |
| 2467 - 2471 |
Preparation and characterization of AgI nanoparticles with controlled size, morphology and crystal structure
Guo YG, Lee JS, Maier J |
| 2473 - 2479 |
Nanoscaled surface structures of ionic crystals by spinodal decomposition
Ringe A, Elter P, Gibhardt H, Eckold G |
| 2481 - 2485 |
X-ray absorption studies of the structure of nanocrystalline oxides
Chadwick AV |
| 2487 - 2490 |
Nonequilibrium cation distribution in nanocrystalline MgAl2O4 spinel studied by Al-27 magic-angle spinning NMR
Sepelak V, Indris S, Bergmann I, Feldhoff A, Becker KD, Heitjans P |
| 2491 - 2494 |
Nanostructuring in composites and grossly nonstoichiometric or heavily doped oxides
Nemudry A, Uvarov N |
| 2495 - 2502 |
Ionic and electronic conduction in nanostructured solids: Concepts and concerns, consensus and controversies
Knauth P |
| 2503 - 2507 |
Anomalous conductivity and microstructure in gadolinium doped ceria prepared from nano-sized powder
Sakai N, Xiong YP, Yamaji K, Yokokawa H, Terashi Y, Seno H |
| 2509 - 2512 |
Electrical properties of nanocrystalline Sm-doped ceria ceramics
Jasinski P |
| 2513 - 2518 |
Microstructures and electrical conductivity of nanocrystalline ceria-based thin films
Rupp JLM, Gauckler LJ |
| 2519 - 2526 |
Structural studies of nanocrystalline oxides
Savin SLP, Chadwick AV, O'Dell LA, Smith ME |
| 2527 - 2531 |
Template synthesis of M/M2S (M = Ag, Cu) hetero-nanowires by electrochemical technique
Liang CH, Terabe K, Hasegawa T, Aono M |
| 2533 - 2538 |
Nanocomposites comprised of doped cerium dioxide and lanthanum manganite for syngas production
Frolova-Borchert YV, Sadykov VA, Alikina GM, Lukashevich AI, Moroz EM, Kochubey DI, Kriventsov VV, Zaikovskii VI, Zyryanov VV, Uvarov NF |
| 2539 - 2541 |
SOFC-anodes, proof for a finite-length type Gerischer impedance?
Boukamp BA, Verbraeken M, Blank DHA, Holtappels P |
| 2543 - 2547 |
Impact of particle size on conductivity and storage capacity as derived from the core-space charge model
Jamnik J |
| 2549 - 2553 |
Modelling of grain boundary resistivities of n-conducting BaTiO3 ceramics
Preis W, Sitte W |
| 2555 - 2559 |
The influence of grain boundary on the conductivity of donor doped SrTiO3
Horikiri F, Han LQ, Kaimai A, Otake T, Yashiro K, Kawada T, Mizusaki J |
| 2561 - 2564 |
Protonic mobility in acidic colloids
Pautrot-d'Alencon L, Barboux P, Carriere D, Lahlil K, Maron S |
| 2565 - 2568 |
New class of soft matter electrolytes obtained via heterogeneous doping: Percolation effects in "soggy sand" electrolytes
Bhattacharyya AJ, Maier J, Bock R, Lange FF |
| 2569 - 2573 |
Conduction in ionic organic plastic crystals: The role of defects
Huang JH, Hill A, Forsyth M, MacFarlane D, Hollenkamp A |
| 2575 - 2579 |
Li3+ ion irradiation effects on ionic conduction in P(VDF-HFP)-(PC+DEC)-LiClO4 gel polymer electrolyte system
Kumar A, Saikia D, Singh F, Avasthi DK |
| 2581 - 2584 |
Ionic conduction pathways in noble metal chalcohalide glasses
Usuki T, Nakajima K, Furukawa T, Onodera Y, Nasu T, Sakurai M, Kohara S |
| 2585 - 2588 |
Effect of nanocrystallization on the electronic conductivity of vanadate-phosphate glasses
Garbarczyk JE, Jozwiak P, Wasiucionek M, Nowinski JL |
| 2589 - 2592 |
An anomalous enhancement in the electrical conductivity of Li2O : B2O3 : Al2O3 glasses
Gedam RS, Deshpande VK |
| 2593 - 2595 |
Vitreous solid state electrolytes in the system of RNO3-Zn(NO3)(2)-KHSO4-P2O5
Perez-Medina JC, Gorokhovsky AV, Escalante-Garcia JI |
| 2597 - 2599 |
Vitrification and transport properties in AgBr-doped chalcogenide systems
Onodera Y, Furukawa T, Hashimoto S, Usuki T, Amo Y, Kameda Y |
| 2601 - 2603 |
Synthesis and electrochemical propeities of Li2S-B2S3-Li4SiO4
Seino Y, Takada K, Kim BC, Zhang LQ, Ohta N, Wada H, Osada M, Sasaki T |
| 2605 - 2609 |
Ionic conductivity and nano-crystallization CuI-Cu2MoO4 glasses
Tsurui T, Kawamura J, Suzuki K |
| 2611 - 2615 |
High lithium ion conductivity glass-ceramics in Li2O-Al2O3-TiO2-P2O5 from nanoscaled glassy powders by mechanical milling
Xu XX, Wen ZY, Yang XL, Zhang JC, Gu ZH |
| 2617 - 2624 |
Diffusional mechanism of deintercalation in LiFe1-yMnyPO4 cathode material
Molenda J, Ojczyk W, Swierczek K, Zajac W, Krok F, Dygas J, Liu RS |
| 2625 - 2628 |
Novel olivine and spinel LiMAsO4 (M=3d-metal) as positive electrode materials in lithium cells
Arroyo-de Dompablo ME, Amador U, Alvarez M, Gallardo JM, Garcia-Alvarado F |
| 2629 - 2634 |
Factors limiting the electrochemical performance of oxide cathodes
Manthiram A, Choi J, Choi W |
| 2635 - 2638 |
LiVPO4F: A new active material for safe lithium-ion batteries
Gover RKB, Burns P, Bryan A, Saidi MY, Swoyer JL, Barker J |
| 2639 - 2642 |
Development and application of combinatorial electrostatic atomization system "M-ist Combi" - High-throughput preparation of electrode materials
Fujimoto K, Kato T, Ito S, Inoue S, Watanabe M |
| 2643 - 2646 |
Mechanism of the memory effect in "Nickel" electrodes
Huggins RA |
| 2647 - 2651 |
Impact of electrochemical wiring topology on the kinetics of insertion electrodes
Gaberscek M, Jamnik J |
| 2653 - 2656 |
Improvement of cycle life of spinel type of lithium manganese oxide by addition of other spinel compounds during synthesis
Hibino M, Nakamura M, Kamitaka Y, Ozawa N, Yao T |
| 2657 - 2660 |
Electrochemical and magnetic properties of Li4/3Mn2/3O2-LiCoO2 solid solution
Nakamura T, Demidzu H, Nakashima D, Yamada Y, Tabuchi M |
| 2661 - 2665 |
Theoretical calculation of electronic structure and X-ray absorption near-edge structure of cathode materials for Li ion batteries
Jeon YA, Kim YS, Kim SK, No KS |
| 2667 - 2674 |
Carbon and transition metal containing titanium phosphates as electrodes for lithium ion batteries
Santos-Pena J, Cruz-Yusta M, Soudan P, Franger S, Cuart-Pascual JJ |
| 2675 - 2678 |
Synthesis and characterization of Cr8O21 as cathode material for rechargeable lithium batteries
Liu JY, Wang ZX, Li H, Huang XJ |
| 2679 - 2682 |
Conductivity and thermal studies of blend polymer electrolytes based on PVAc-PMMA
Baskaran R, Selvasekarapandian S, Kuwata N, Kawamura J, Hattori T |
| 2683 - 2686 |
High ionic conductive behavior of cyanoethylated polyvinylalcohol- and polyacrylonitrile-based electrolytes
Tsutsumi H, Kitagawa T |
| 2687 - 2690 |
Super-pressed and super-cooled (?) P(EO)(20)LiBETI
Booher KR, Passerini S, Edmondson CA, Fontanella JJ |
| 2691 - 2697 |
Lithium salt dissociation in non-aqueous electrolytes modeled by ab initio calculations
Johansson P, Jacobsson P |
| 2699 - 2704 |
Polyphosphazene based composite polymer electrolytes
Kaskhedikar N, Paulsdorf J, Burjanadze A, Karatas Y, Roling B, Wiemhofer HD |
| 2705 - 2709 |
M/Li+ (M = Mg2+, Zn2+, and Mn2+) ion-exchange on lithium ion-conducting perovskite-type oxides and their properties
Inaguma Y, Mashiko W, Watanabe M, Atsumi Y, Okuyama N, Katsumata T, Ohba T |
| 2711 - 2714 |
Mesopore size dependence of the ionic diffusivity in alumina based composite lithium ionic conductors
Maekawa H, Fujimaki Y, Shen HY, Kawamura J, Yamamura T |
| 2715 - 2720 |
Recent progress of glass and glass-ceramics as solid electrolytes for lithium secondary batteries
Minami T, Hayashi A, Tatsumisago M |
| 2721 - 2725 |
High lithium ion conducting glass-ceramics in the system Li2S-P2S5
Mizuno F, Hayashi A, Tadanaga K, Tatsumisago M |
| 2727 - 2730 |
Li+ ion conducting properties in (Gd,La)(2)O-3-LiNO3-KNO3 solid
Tamura S, Mori A, Imanaka N |
| 2731 - 2735 |
High rate performances of all-solid-state In/LiCoO2 cells with the Li2S-P2S5 glass-ceramic electrolytes
Mizuno F, Hayashi A, Tadanaga K, Tatsumisago M |
| 2737 - 2740 |
Formation of electrode-electrolyte interface by lithium insertion to SnS-P2S5 negative electrode materials in all-solid-state cells
Hayashi A, Konishi T, Tadanaga K, Tatsumisago M |
| 2741 - 2746 |
Lithium diffusion in rutile structured titania
Gligor F, de Leeuw SW |
| 2747 - 2751 |
Correlation of glass transition temperature and density with electrical conductivity of lithium sulfoborosilicate glasses
Deshpande AV, Deshpande VK |
| 2753 - 2757 |
Lithium ion conducting solid electrolytes prepared from Li2S, elemental P and S
Mizuno F, Ohtomo T, Hayashi A, Tadanaga K, Tatsumisago M |
| 2759 - 2768 |
Characterization of proton exchanged Li4Ti5O12 spinel material
Simon DR, Kelder EM, Wagemaker M, Mulder FM, Schoonman J |
| 2769 - 2773 |
Electrochemical modification of spinel oxide materials using lithium solid state electrolyte
Mateyshina YG, Uvarov NF, Ulihin AS, Pavlyukhin YT |
| 2775 - 2778 |
Li+ ionic diffusion in Li-Cu-O compounds
Nakamura K, Kawai K, Yamada K, Michihiro Y, Moriga T, Nakabayashi I, Kanashiro T |
| 2779 - 2785 |
Characteristic changes under pulsed pressure action in electrode materials based on LiMn2O4 and Li4Ti5O12 spinels
Nikonov AV, Kelder EM, Schoonman J, Ivanov VV, Pivkin NM |
| 2787 - 2790 |
Composite solid electrolytes LiClO4-Al2O3
Ulihin AS, Uvarov NF, Mateyshina YG, Brezhneva LI, Matvienko AA |
| 2791 - 2799 |
Improve the electrochemical performances of Cr2O3 anode for lithium ion batteries
Hu J, Li H, Huang XJ, Chen LQ |
| 2801 - 2806 |
Graphite surface disorder detection using in situ Raman microscopy
Hardwick LJ, Buqa H, Novak P |
| 2807 - 2810 |
Electrochemical performances of silicon electrode with silver additives
Yang XL, Wen ZY, Huang SH, Zhu XJ, Zhang XF |
| 2811 - 2819 |
Progress in three-dimensional (3D) Li-ion microbatteries
Golodnitsky D, Nathan M, Yufit V, Strauss E, Freedman K, Burstein L, Gladkich A, Peled E |
| 2821 - 2825 |
Formation and characterization of SnO2 nanobaskets
Johnson PL, Teeters D |
| 2827 - 2832 |
Thin film lithium ion batteries prepared only by pulsed laser deposition
Kuwata N, Kumar R, Toribami K, Suzuki T, Hattori T, Kawamura J |
| 2833 - 2838 |
Characterization of lithium nanobatteries and lithium battery nanoelectrode arrays that benefit from nanostructure and molecular self-assembly
Vullum F, Teeters D, Nyten A, Thomas J |
