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Ionic mixed

The anode material in SOF(7s is a cermet (rnetal/cerarnic composite material) of 30 to 40 percent nickel in zirconia, and the cathode is lanthanum rnanganite doped with calcium oxide or strontium oxide. Both of these materials are porous and mixed ionic/electronic conductors. The bipolar separator typically is doped lanthanum chromite, but a metal can be used in cells operating below 1073 K (1472°F). The bipolar plate materials are dense and electronically conductive. [Pg.2413]

Table 11.2 and assume A=100, which is rather conservative value, to compute J via Eq. (11.32) and O via Eq. (11.22). The results show t p 0.91 which implies that the O2 backspillover mechanism is fully operative under oxidation reaction conditions on nanoparticle metal crystallites supported on ionic or mixed ionic-electronic supports, such as YSZ, Ti02 and Ce02. This is quite reasonable in view of the fact that, as already mentioned an adsorbed O atom can migrate 1 pm per s on Pt at 400°C. So unless the oxidation reaction turnover frequency is higher than 103 s 1, which is practically never the case, the O8 backspillover double layer is present on the supported nanocrystalline catalyst particles. [Pg.509]

There are no specific requirements for the solid electrolytes (pellets or tubes) used in electrochemical promotion experiments. However they should be stable under the conditions of the experimental study. Also one should know the type of ionic conductivity and the possibility of appearance of mixed ionic-electronic conductivity under the conditions of electrochemical promotion. This is quite essential for the correct interpretation of results. Addresses of suppliers of solid electrolytes included in Table B.l are presented below ... [Pg.547]

The conductivities of melts, in contrast to those of aqueous solutions, increase with decreasing crystal radius of the anions and cations, since the leveling effect of the solvation sheaths is absent and ion jumps are easier when the radius is small. In melts constituting mixtures of two salts, positive or negative deviations from additivity are often observed for the values of conductivity (and also for many other properties). These deviations arise for two reasons a change in hole size and the formation of new types of mixed ionic aggregates. [Pg.133]

Many types of oxide layers have a certain, not very high electrical conductivity of up to 10 to 10 S/cm. Conduction may be cationic (by ions) or anionic (by or OH ions), or of the mixed ionic and electronic type. Often, charge transport occurs by a semiconductor hole-type mechanism, hence, oxides with ionic and ionic-hole conduction are distinguished (in the same sense as p-type and n-type conduction in the case of semiconductors, but here with anions or cations instead of the electrons, and the corresponding ionic vacancies instead of the electron holes). Electronic conduction is found for the oxide layers on iron group metals and on chromium. [Pg.303]

Double Substitution In such processes, two substitutions take place simultaneously. For example, in perovskite oxides, La may be replaced by Sr at the same time as Co is replaced by Fe to give solid solutions Lai Sr Coi yFey03 5. These materials exhibit mixed ionic and electronic conduction at high temperatures and have been used in a number of applications, including solid oxide fuel cells and oxygen separation. [Pg.425]

Solid mixed ionic-electronic conductors (MIECs) exhibit both ionic and electronic (electron-hole) conductivity. Naturally, in any material there are in principle nonzero electronic and ionic conductivities (a i, a,). It is customary to limit the use of the term MIEC to those materials in which a, and 0, 1 do not differ by more than two orders of magnitude. It is also customary to use the term MIEC if a, and Ogi are not too low (o, a i 10 S/cm). Obviously, there are no strict rules. There are processes where the minority carriers play an important role despite the fact that 0,70 1 exceeds those limits and a, aj,i< 10 S/cm. In MIECs, ion transport normally occurs via interstitial sites or by hopping into a vacant site or a more complex combination based on interstitial and vacant sites, and electronic (electron/hole) conductivity occurs via delocalized states in the conduction/valence band or via localized states by a thermally assisted hopping mechanism. With respect to their properties, MIECs have found wide applications in solid oxide fuel cells, batteries, smart windows, selective membranes, sensors, catalysis, and so on. [Pg.436]

Surfactants employed for w/o-ME formation, listed in Table 1, are more lipophilic than those employed in aqueous systems, e.g., for micelles or oil-in-water emulsions, having a hydrophilic-lipophilic balance (HLB) value of around 8-11 [4-40]. The most commonly employed surfactant for w/o-ME formation is Aerosol-OT, or AOT [sodium bis(2-ethylhexyl) sulfosuccinate], containing an anionic sulfonate headgroup and two hydrocarbon tails. Common cationic surfactants, such as cetyl trimethyl ammonium bromide (CTAB) and trioctylmethyl ammonium bromide (TOMAC), have also fulfilled this purpose however, cosurfactants (e.g., fatty alcohols, such as 1-butanol or 1-octanol) must be added for a monophasic w/o-ME (Winsor IV) system to occur. Nonionic and mixed ionic-nonionic surfactant systems have received a great deal of attention recently because they are more biocompatible and they promote less inactivation of biomolecules compared to ionic surfactants. Surfactants with two or more hydrophobic tail groups of different lengths frequently form w/o-MEs more readily than one-tailed surfactants without the requirement of cosurfactant, perhaps because of their wedge-shaped molecular structure [17,41]. [Pg.472]

Wang, L., Tahor, R., Eastoe, J., Li, X., Heenan, R.K. and Dong, J. (2009) Formation and stability of nanoemulsions with mixed ionic—nonionic surfactants. Physical Chemistry Chemical Physics, 11, 9772-9778. [Pg.174]

Another problem that is common for all membrane-based solid-state sensors is the ill-defined membrane-metal interface. A large exchange current density is required to produce a reversible interface for a stable potentiometric sensor response. One approach to improving this interface is to use conducting polymers. Conducting polymers are electroactive n-conjugated polymers with mixed ionic and electronic conductivity. They... [Pg.304]

The surface sites and complexes lie in a layer on the mineral surface which, because of the charged complexes, has a net electrical charge that can be either positive or negative. A second layer, the diffuse layer, separates the surface layer from the bulk fluid. The role of the diffuse layer is to achieve local charge balance with the surface hence, its net charge is opposite that of the sorbing surface. Double layer theory, applied to a mixed ionic solution, does not specify which ions make up the diffuse layer. [Pg.157]

Pure and doped ceria are mixed ionic and electronic conductors under reducing atmospheres, due to considerable p-type electronic conductivity under reducing conditions. The electronic conduction is due to the reduction of Cc4 to Ce3+ under... [Pg.47]

In this chapter the technological development in cathode materials, particularly the advances being made in the material s composition, fabrication, microstructure optimization, electrocatalytic activity, and stability of perovskite-based cathodes will be reviewed. The emphasis will be on the defect structure, conductivity, thermal expansion coefficient, and electrocatalytic activity of the extensively studied man-ganite-, cobaltite-, and ferrite-based perovskites. Alterative mixed ionic and electronic conducting perovskite-related oxides are discussed in relation to their potential application as cathodes for ITSOFCs. The interfacial reaction and compatibility of the perovskite-based cathode materials with electrolyte and metallic interconnect is also examined. Finally the degradation and performance stability of cathodes under SOFC operating conditions are described. [Pg.132]

This is not exactly the order as the electronic conductivity of the oxides, indicating that electrocatalytic activity of mixed ionic and electronic conducting (MIEC) oxides depends on other properties such as the oxygen exchange and ionic conductivities. [Pg.152]

The suitability of lanthanum nickelate as an SOFC cathode has been examined by Virkar s group [138], They showed that LN performed poorly as a single-phase cathode in an anode-supported YSZ cell. However, with an SDC/LN composite interlayer the performance of the LN cathode increased substantially and the maximum power density of the cell with a YSZ thin electrolyte (-8 pm) was -2.2 Wear2 at 800°C, considerably higher than 0.3 to 0.4 Wcm-2 of similar cells with only LN or SDC interlayer. The results are significant as it shows that the composite MIEC cathodes perform much better than single-phase MIEC in the case of LN despite its mixed ionic and electronic conductivity. [Pg.156]

D Mixed ionic electronic conductor (MIEC) o Triple-phase boundaries (TPB s)... [Pg.243]

Wan J, Goodenough JB, and Zhu JH. Nd2 xLaxNi04+5, a mixed ionic/electronic conductor with interstitial oxygen, as a cathode material. Solid State Ionics 2007 178 281-286. [Pg.277]

The thermodynamics of insertion electrodes is discussed in detail in Chapter 7. In the present chapter attention is focused mainly on the general kinetic aspects of electrode reactions and on the techniques by which the transport of species within electrodes may be determined. The electrodes are treated in a general fashion as exhibiting mixed ionic and electronic transport, and attention is concentrated on the description of the coupled transport of these species. In this context it is useful to consider that an electronically conducting lead provides the electrons at the electrodes and compensates the charges of the ions transferred by the electrolyte. [Pg.199]

The diffusivity is independent of the motion of any other species (e.g. electrons or holes) and is not influenced by internal electrical fields as in the case of chemical diffusion processes which require the simultaneous motion of electronic or other ionic species. The partial ionic conductivity of the mixed ionic and (predominantly) electronic conducting electrode is given by the product of the concentration and the diffusivity and may be related to the variations of the steady state and transient voltage ... [Pg.226]

In conclusion, mention should be made of glass electrodes exhibiting mixed, ionic and electronic conductances. A chalcogenide glass (28% Ge, 60% Se, 12%... [Pg.161]


See other pages where Ionic mixed is mentioned: [Pg.44]    [Pg.351]    [Pg.15]    [Pg.94]    [Pg.337]    [Pg.179]    [Pg.210]    [Pg.436]    [Pg.437]    [Pg.437]    [Pg.742]    [Pg.88]    [Pg.52]    [Pg.126]    [Pg.351]    [Pg.379]    [Pg.320]    [Pg.328]    [Pg.146]    [Pg.243]    [Pg.650]    [Pg.172]    [Pg.173]    [Pg.2]    [Pg.50]    [Pg.22]    [Pg.253]   
See also in sourсe #XX -- [ Pg.36 , Pg.72 ]




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Challenges in Modeling Mixed Ionic-Covalent Glass Formers

Conductivity mixed electronic/ionic

Covalent-ionic mixing

Covalent-ionic state mixing

Diffusion in Mixed Electronic-Ionic Conducting Oxides (MEICs)

Ionic-covalent mixed oxides

Ionic-nonionic mixed micelles

Ionic-nonionic mixed micelles ideality

Ionic-nonionic mixed micelles negative deviation from

MIEC (mixed ionic/electronic

Mixed Ionic/electron

Mixed ionic and electronic conductance

Mixed ionic and electronic conducting

Mixed ionic and electronic conducting material

Mixed ionic and electronic conducting membrane

Mixed ionic and electronic conducting oxides

Mixed ionic and electronic conductivity MIEC) membranes

Mixed ionic and electronic conductivity membranes

Mixed ionic electronic conduction electrodes

Mixed ionic electronic conductive material

Mixed ionic electronic conductive material MIEC)

Mixed ionic electronic conductivity (MIEC

Mixed ionic-electronic

Mixed ionic-electronic conducting

Mixed ionic-electronic conductive

Mixed ionic-electronic conductive MIEC)

Mixed ionic-electronic conductor MIEC)

Mixed ionic-electronic conductors

Mixed ionic-electronic conductors MIECs)

Mixed ionic—electronic conduction

Mixed oxides with ionic conductivity

Mixed oxygen-ionic and electronic

Mixed-aqueous solvent, ionication

Non-ionic surfactants mixed EO/PO compounds

Solid mixed ionic-electronic conductors

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