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- ISBN: 9781558999299 | 1558999299
- Cover: Hardcover
- Copyright: 4/2/2007
Solid-state ionics is at the foundation for the developmentally friendly devices such as batteries and fuel cells for energy storage and conversion, and chemical sensors for pollution monitoring and control.
Mixed-conducting membranes for hydrogen production and separation | p. 3 |
Proton diffusion in hydrated acceptor-doped barium zirconate | p. 15 |
Study on the perovskite-type oxide cathodes in proton-conducting SOFC | p. 21 |
Synthesis and characterization of BaZr[subscript 0.8]Y[subscript 0.2]O[subscript 3] protonic conductor for intermediate temperature solid oxide fuel cells (IT-SOFCs) | p. 31 |
Supported high temperature protonic films produced by solid state reaction | p. 37 |
Cell performance stability of HMFC using Ba(Ce[subscript 1-x]Zr[subscript x])[subscript 0.8]Y[subscript 0.2]O[subscript 3] perovskite type proton conductor as electrolyte | p. 45 |
Solid oxide fuel cells based on proton conducting electrolytes | p. 55 |
Ionic conduction in nanoscale films of yttrium-doped barium zirconate | p. 63 |
Ab Initio study of oxygen-vacancy ordering in oxygen conducting Ba[subscript 2]In[subscript 2]O[subscript 5] | p. 71 |
Interfacial structure and point defects in Ceria/Zirconia superlattices | p. 77 |
Assembly of decavanadate polyanions by Collagen helices : synthesis of an hybrid inorganic-bioorganic material | p. 85 |
Electrochemical synthesis of lamellar structured inorganic films using interfacial surfactant templating | p. 91 |
Structural characterization and ionic conductivity of metastable Gd[subscript 2](Ti[subscript 0.65]Zr[subscript 0.35])[subscript 2]O[subscript 7] powders prepared by mechanical milling | p. 97 |
Room-temperature synthesis and electrical properties of La, Nd and Gd apatite-type silicates | p. 103 |
Mixed conductivity and oxygen permeability of (Ba[subscript x]Sr[subscript 1-x])[subscript 0.98]Fe[subscript 1-y]M[subscript y]O[subscript 3-[delta]] (x = 0.1-0.3, y = 0.1-0.4 and M = Ga, Al) | p. 111 |
Characterization of (La[subscript 0.9]Sr[subscript 0.1])[subscript 0.95]Cr[subscript 0.85]Mg[subscript 0.1]Ni[subscript 0.05]O[subscript 3] perovskite ceramics for a perovskite related membrane reactor | p. 117 |
New polybenzimidazole-based membranes for fuel cells | p. 125 |
State of water in nafion 117 proton exchange membranes studied by dielectric relaxation spectroscopy | p. 131 |
New strategies on SOFC | p. 139 |
High performance single step Co-fired solid oxide fuel cells | p. 149 |
Scandia-stabilized zirconia : effect of dopants on surface/grain boundary segregation and transport properties | p. 155 |
Processing and characterization of Sc[subscript 2]O[subscript 3]-CeO[subscript 2]-ZrO[subscript 2] electrolyte based intermediate temperature solid oxide fuel cells | p. 163 |
Synthesis and densification of nanometric Ce[subscript 0.8]Sm[subscript 0.2]O[subscript 1.9-[delta]] | p. 169 |
Electrochemical characterization of La[subscript 2-x]Pr[subscript x]NiO[subscript 4+x] for application as cathodes in intermediate temperature SOFCs | p. 175 |
Low temperature synthesis and electrochemical properties of M[subscript 0.8]Sr[subscript 0.2]Co[subscript 1-x]Fe[subscript x]O[subscript 3] (M = Ba, La, Pr) nanoparticles : effect of grain size on lattice symmetry | p. 181 |
Sintering behavior and phase characterization of composite perovskite/fluorite ceramics for intermediate temperature SOFCs and oxygen separation membranes | p. 187 |
Electrochemical properties of nanocrystalline Y[subscript 2-x]Pr[subscript x]Ru[subscript 2]O[subscript 7] pyrochlore for electrodic application in IT-SOFCs | p. 193 |
Refractory cathode investigation for single-step co-fired solid oxide fuel cells (SOFCs) | p. 199 |
Design of anodes for IT SOFC : effect of complex oxide promoters and Pd on activity and stability in methane steam reforming of Ni/YSZ (ScSZ) cermets | p. 205 |
Direct-write microfabrication of single-chamber solid oxide fuel cells with interdigitated electrodes | p. 211 |
Materials and design study for micromachined solid oxide fuel cells membranes | p. 217 |
A survey of diverse approximations for microstructural characterization using powder diffraction data : [beta]-Ni(OH)[subscript 2] : a case study | p. 227 |
Enabling aspects of metal halide nanocomposites for reversible energy storage | p. 239 |
Influences of microstructures of the cathode/electrolyte interface on the electrochemical properties of all solid-state Li-ion batteries | p. 251 |
Intermediate phases in Li[subscript x]FePO[subscript 4] | p. 257 |
Characterization of the carbon-coating of LiFePO[subscript 4] by transmission electron microscopy and Raman spectroscopy | p. 265 |
The hydrothermal synthesis of lithium iron phosphate | p. 271 |
Local structure and magnetic properties of Li[subscript x]FePO[subscript 4] glasses | p. 277 |
A new lithium iron phosphate LiFe[subscript 2]P[subscript 3]O[subscript 10] synthesized at 600[degrees]C from precursor obtained by wet chemistry | p. 283 |
Impact of surface chemistry on the electrochemical performance of LiCoO[subscript 2] | p. 289 |
Analysis of composition and valence states in positive electrode materials (Fe-substituted Li[subscript 2]MnO[subscript 3]) for lithium ion batteries by analytical transmission electron microscopy | p. 295 |
Influence of lithium content on performance of layered Li[subscript 1+z]Ni[subscript 0.45]Mn[subscript 0.45]Co[subscript 0.1]I[subscript 1-z]O[subscript 2] in lithium ion batteries | p. 301 |
Role of rare-earth element doping in the cycleability of LiMn[subscript 2]O[subscript 4] cathodes for Li-ion rechargeable batteries | p. 307 |
Effect of ZnO coating on the electrochemical performance of LiMn[subscript 1.5]Ni[subscript 0.5]O[subscript 4] cathode material | p. 313 |
Li batteries with porous sol-gel cathodes | p. 319 |
Magnetic studies of layered cathode materials for lithium ion batteries | p. 325 |
Preparation and characterization of ALD TiN thin films on lithium titanate spinel (Li[subscript 4]Ti[subscript 5]O[subscript 12]) for lithium ion battery applications | p. 331 |
Safety characteristics of the Li[subscript 4]Ti[subscript 5]O[subscript 12]/LiMn[subscript 2]O[subscript 4] Li-ion battery | p. 339 |
Preparation and characterization of Li[subscript 4/3]Ti[subscript 5/3]O[subscript 4] thin films by sol-gel method | p. 345 |
Synthesis and electrochemistry of acicular silver vanadium oxide nanofibers | p. 351 |
Nanosized amorphous materials as anodes for lithium batteries | p. 357 |
Li[subscript x] C[subscript n] as anode material for lithium ion batteries | p. 363 |
Potentiometric detection of VOCs using non-nernstian SmFeO[subscript 3]/Pt/YSZ/Pt sensors | p. 373 |
Impedancemetric technique for NO[subscript x] sensing using a YSZ-based electrochemical cell | p. 379 |
Impedance analysis of electrochemical NO[subscript x] sensor using a Au/Yttria-stabilized zirconia (YSZ)/Au cell | p. 385 |
Preparation of SrFeO[subscript 3-x] thin films by the spin-coating method and its gas sensing properties | p. 391 |
Merits of Bi[subscript 3]TiNbO[subscript 9] for humidity sensors | p. 397 |
Electrochromic nickel hydroxide thin films chemically deposited | p. 405 |
Effect of water on the IR properties of Mg[superscript 2+] intercalated electrochromic Nb[subscript 2]O[subscript 5] thin films | p. 411 |
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