Access the full text.
Sign up today, get DeepDyve free for 14 days.
Kaveh Partovi, Fangyi Liang, Olga Ravkina, J. Caro (2014)
High-flux oxygen-transporting membrane Pr(0.6)Sr(0.4)Co(0.5)Fe(0.5)O(3-δ): CO2 stability and microstructure.ACS applied materials & interfaces, 6 13
V. Belousov (2004)
Rapid Nondiffusional Penetration of Oxide Melts along Grain Boundaries of Oxide CeramicsJournal of the American Ceramic Society, 82
S. Ramamurthy, M. Mallamaci, C. Zimmerman, C. Carter, P. Duncombe, T. Shaw (1996)
Microstructure of Polycrystalline MgO Penetrated by a Silicate LiquidMicroscopy and Microanalysis, 2
J. Feinleib, D. Adler (1968)
Band Structure and Electrical Conductivity of NiOPhysical Review Letters, 21
W. Read, W. Shockley (1950)
Dislocation Models of Crystal Grain BoundariesPhysical Review, 78
J. Cahn (1977)
Critical point wettingJournal of Chemical Physics, 66
T. Shaw, P. Duncombe (1991)
Forces between Aluminum Oxide Grains in a Silicate Melt and Their Effect on Grain Boundary WettingJournal of the American Ceramic Society, 74
(1978)
Phase equilibrium in Cu-V-O system
V. Belousov, A. Klimashin (2012)
Catastrophic Oxidation of Copper: A Brief ReviewMetallurgical and Materials Transactions A, 43
Doh-Yeon Kim, S. Wiederhorn, B. Hockey, C. Handwerker, J. Blendell (1994)
Stability and Surface Energies of Wetted Grain Boundaries in Aluminum OxideJournal of the American Ceramic Society, 77
V. Belousov, A. Klimashin (2013)
High-temperature oxidation of copperRussian Chemical Reviews, 82
T. Bak, J. Nowotny, M. Rȩkas, C. Sorrell, P. Banda, W. Wlodarski (2002)
Electrical conductivity of indium sesquioxide thin filmJournal of Materials Science: Materials in Electronics, 13
R. Pashley, J. Israelachvili (1984)
Molecular layering of water in thin films between mica surfaces and its relation to hydration forcesJournal of Colloid and Interface Science, 101
M. Sasabe, K. Goto (1974)
Permeability, diffusivity, and solubility of oxygen gas in liquid slagMetallurgical Transactions, 5
V. Belousov, S. Fedorov, A. Vorobiev (2011)
The Oxygen Permeation of Solid/Melt Composite BiVO4 – 10 wt % V2O5 MembraneJournal of The Electrochemical Society, 158
(1966)
On the CuO-V2O5 system
G. Garcia‐Belmonte, J. Bisquert (2004)
Interpretation of the critical length scale determining the conductivity in ionically conducting silicate glassesJournal of Non-crystalline Solids, 337
I. Kulbakin, V. Belousov, S. Fedorov, A. Vorobiev (2012)
Solid/melt ZnO–Bi2O3 composites as ion transport membranes for oxygen separation from airMaterials Letters, 67
B. Widom (1978)
Structure of the αγ interfaceJournal of Chemical Physics, 68
J. Gambino, W. Kingery, G. Pike, L. Levinson, H. Philipp (1989)
Effect of Heat Treatments on the Wetting Behavior of Bismuth‐Rich Intergranular Phases in ZnO:Bi:Co VaristorsJournal of the American Ceramic Society, 72
N. Toshima (1992)
Polymers for gas separation
G. Teletzke, L. Scriven, H. Davis (1982)
Wetting transitions. II. First order or second orderJournal of Chemical Physics, 77
D. Clarke (1987)
On the Equilibrium Thickness of Intergranular Glass Phases in Ceramic MaterialsJournal of the American Ceramic Society, 70
Cynthia Powell‐Doǧan, A. Heuer (1990)
Microstructure of 96% Alumina Ceramics: I, Characterization of the As‐Sintered MaterialsJournal of the American Ceramic Society, 73
Konrad Colombo, V. Kharton, O. Bolland (2010)
Simulation of an Oxygen Membrane-Based Gas Turbine Power Plant: Dynamic Regimes with Operational and Material ConstraintsEnergy & Fuels, 24
P. Gennes (1981)
Some effects of long range forces on interfacial phenomenaJournal De Physique Lettres, 42
V. Belousov, A. Klimashin, S. Fedorov (2016)
Modeling oxygen Ion transport of molten oxide membranes based on V2O5Ionics, 22
R. French (2004)
Origins and Applications of London Dispersion Forces and Hamaker Constants in CeramicsJournal of the American Ceramic Society, 83
Tobias Klande, Olga Ravkina, A. Feldhoff (2013)
Effect of A-site lanthanum doping on the CO2 tolerance of SrCo0.8Fe0.2O3−-δ oxygen-transporting membranesJournal of Membrane Science, 437
H. Stanley (2008)
Phase Transitions and Critical PhenomenaBulletin of the American Physical Society
D. Susnitzky, C. Carter (1990)
Structure of Alumina Grain Boundaries Prepared with and without a Thin Amorphous Intergranular FilmJournal of the American Ceramic Society, 73
A. Janotti, C. Walle (2009)
Fundamentals of zinc oxide as a semiconductorReports on Progress in Physics, 72
A. Klimashin, V. Belousov (2015)
Mechanism of oxygen ion transfer in oxide melts based on V2O5Russian Journal of Physical Chemistry A, 90
R. Horn, J. Israelachvili (1980)
Direct measurement of forces due to solvent structureChemical Physics Letters, 71
(1998)
Inorganic membranes. In: Sikar KK, Lloyd DR (eds) AIChE Symp. Ser. new membrane materials and processes of separation
E. Capoen, M. Steil, G. Nowogrocki, M. Malys, C. Pirovano, A. Löfberg, E. Bordes-Richard, J. Boivin, G. Mairesse, R. Vannier (2006)
Oxygen permeation in bismuth-based materials. Part I: Sintering and oxygen permeation fluxesSolid State Ionics, 177
V. Belousov (2014)
Oxygen Permeation of Partly Molten SlagsMetallurgical and Materials Transactions A, 45
(1980)
The diffraction analysis of high temperature melt structure
P. Battle, C. Catlow, J. Drennan, A. Murray (1983)
The structural properties of the oxygen conducting δ phase of Bi2O3Journal of Physics C: Solid State Physics, 16
V. Belousov (1995)
Liquid-channel grain-boundary structures with ionic conductionRussian Journal of Electrochemistry, 31
V. Belousov (2007)
Mechanisms of Accelerated Oxidation of Copper in the Presence of Molten OxidesOxidation of Metals, 67
V. Belousov (2007)
Surface ionics : A brief reviewJournal of The European Ceramic Society, 27
M. Fujimoto, W. Kingery (1985)
Microstructures of SrTiO3 Internal Boundary Layer Capacitors During and After Processing and Resultant Electrical PropertiesJournal of the American Ceramic Society, 68
E. Capoen, G. Nowogrocki, R. Chater, S. Skinner, J. Kilner, M. Malys, J. Boivin, G. Mairesse, R. Vannier (2006)
Oxygen permeation in bismuth-based materials. Part II: Characterisation of oxygen transfer in bismuth erbium oxide and bismuth calcium oxide ceramicSolid State Ionics, 177
(1990)
The structure of V2O5-K2SO4 and KVO3-K2S2O7 melts according to NMR data
VV Belousov (1995)
Ion-conducting liquid-channel grain-boundary structuresRuss J Electrochem, 31
V. Belousov (2013)
Oxygen-permeable membrane materials based on solid or liquid Bi_2O_3MRS Communications, 3
V. Belousov (2008)
High-temperature solid/melt nanocompositesJETP Letters, 88
A. Adamson (1960)
Physical chemistry of surfaces
A. Bose, G. Stiegel, P. Armstrong, Barry Halper, E. Foster (2009)
Progress in Ion Transport Membranes for Gas Separation Applications
Micheal Bailey, S. Consonni, Jonathan Forsyth, M. Gatti, E. Martelli, Yasushi Moryi, K. Ogura, F. Viganò (1990)
Separation of GasesEnergy Exploration & Exploitation, 8
Haifeng Wang, Y. Chiang (2005)
Thermodynamic Stability of Intergranular Amorphous Films in Bismuth‐Doped Zinc OxideJournal of the American Ceramic Society, 81
R. Brydson, Shih-Chieh Chen, F. Riley, S. Milne, Xiaoqing Pan, M. Rühle (2005)
Microstructure and Chemistry of Intergranular Glassy Films in Liquid‐Phase‐Sintered AluminaJournal of the American Ceramic Society, 81
D. Newbury, David Williams (2000)
The electron microscope: the materials characterization tool of the millennium☆Acta Materialia, 48
H. Harwig, A. Gerards (1978)
Electrical properties of the α, β, γ, and δ phases of bismuth sesquioxideJournal of Solid State Chemistry, 26
(1984)
The electrical properties of non-stoichiometric oxide melts
(1957)
The conductivity of the oxides of vanadium, lead and copper
V. Belousov, V. Schelkunov, S. Fedorov, I. Kulbakin, A. Vorobiev (2012)
Oxygen-permeable NiO/54 wt% δ-Bi2O3 composite membraneElectrochemistry Communications, 20
P. Zeng, Zhihao Chen, Wei Zhou, Hongxia Gu, Zongping Shao, Shaomin Liu (2007)
Re-evaluation of Ba0.5Sr0.5Co0.8Fe0.2O3- δ perovskite as oxygen semi-permeable membraneJournal of Membrane Science, 291
A. Bunde, M. Ingram, P. Maass (1994)
The dynamic structure model for ion transport in glassesJournal of Non-crystalline Solids
R. Yang (1987)
Gas Separation by Adsorption Processes
F. Richardson (1982)
Interfacial Phenomena and Metallurgical ProcessesCanadian Metallurgical Quarterly, 21
K. Efimov, Tobias Klande, Nadine Juditzki, A. Feldhoff (2012)
Ca-containing CO2-tolerant perovskite materials for oxygen separationJournal of Membrane Science, 389
(1987)
Metal and slag melts: structure and prospects of the study
T. Mazanec (1994)
Prospects for ceramic electrochemical reactors in industrySolid State Ionics
A.R Smith, J. Klosek (2001)
A review of air separation technologies and their integration with energy conversion processesFuel Processing Technology, 70
Zhenbao Zhang, Yubo Chen, M. Tadé, Yong Hao, Shaomin Liu, Zongping Shao (2014)
Tin-doped perovskite mixed conducting membrane for efficient air separationJournal of Materials Chemistry, 2
P. Dyer, R. Richards, S. Russek, D. Taylor (2000)
Ion transport membrane technology for oxygen separation and syngas productionSolid State Ionics, 134
D. Tabor, R. Winterton (1969)
The direct measurement of normal and retarded van der Waals forcesProceedings of the Royal Society of London. A. Mathematical and Physical Sciences, 312
AC Bose, GJ Stiegel, PA Armstrong, BJ Helper, EP Foster (2009)
Inorganic membranes for energy and environmental application
M. Arnold, T. Gesing, J. Martynczuk, A. Feldhoff (2008)
Correlation of the Formation and the Decomposition Process of the BSCF Perovskite at Intermediate TemperaturesChemistry of Materials, 20
V. Belousov (2004)
Wetting of Grain Boundaries in Ceramic MaterialsColloid Journal, 66
S. Baranovskii, H. Cordes (1999)
On the conduction mechanism in ionic glassesJournal of Chemical Physics, 111
Valerii Belousov, S Fedorov (2012)
Accelerated mass transfer involving the liquid phase in solidsRussian Chemical Reviews, 81
Jian Luo, Y. Chiang (1999)
Equilibrium-thickness Amorphous Films on {} surfaces of Bi2O3-doped ZnOJournal of The European Ceramic Society, 19
PP Arsentiev, VV Yakovlev, VV Krashennikov (1988)
Physico-chemical methods of investigation of metallurgical processes
Jian Luo, Y. Chiang (2000)
Existence and stability of nanometer-thick disordered films on oxide surfacesActa Materialia, 48
I. Kul’bakin, S. Fedorov, A. Vorob’ev, V. Belousov (2010)
Transport properties of ZrV2O7-V2O5 composites with liquid-channel grain boundary structureRussian Journal of Electrochemistry, 49
C. Kittel (1954)
Introduction to solid state physics
H. Bouwmeester, H. Kruidhof, A. Burggraaf (1994)
Importance of the surface exchange kinetics as rate limiting step in oxygen permeation through mixed-conducting oxidesSolid State Ionics, 72
D. Craig, F. Hummel (1972)
Zirconium Pyrovanadate TransitionsJournal of the American Ceramic Society, 55
DR Clarke, ML Gee (1992)
Materials interfaces
V. Belousov (2005)
Grain boundary wetting in ceramic cupratesJournal of Materials Science, 40
S. Fedorov, V. Belousov, A. Vorobiev (2008)
Transport Properties of BiVO4 – V2O5 Liquid-Channel Grain-Boundary StructuresJournal of The Electrochemical Society, 155
S. Hull (2004)
Superionics: crystal structures and conduction processesReports on Progress in Physics, 67
A. Bunde, M. Ingram, P. Maass, K. Ngai (1991)
Diffusion with memory: a model for mixed alkali effects in vitreous ionic conductorsJournal of Physics A, 24
HP Hsieh (1998)
AIChE Symp. Ser. new membrane materials and processes of separation
SD Baranovskii, H Cordes (1999)
On the transport mechanism in ionic glassesJ Chem Phys, 111
M. Shin, J. Yu (2012)
Oxygen transport of A-site deficient Sr1−xFe0.5Co0.5O3−δ (x = 0–0.3) membranesJournal of Membrane Science, 401
M. Fisher (2021)
Phase Transitions and Critical PhenomenaStatistical and Thermal Physics
M. Vogel (2004)
Identification of lithium sites in a model of LiPO 3 glass: Effects of the local structure and energy landscape on ionic jump dynamicsPhysical Review B, 70
H. Harwig, A. Gerards (1979)
The polymorphism of bismuth sesquioxideThermochimica Acta, 28
Jian Luo, Haifeng Wang, Y. Chiang (1999)
Origin of Solid‐State Activated Sintering in Bi2O3‐Doped ZnOJournal of the American Ceramic Society, 82
P Zeng, Z Chen, W Zhou, H Gu, Z Shao, S Liu (2007)
Re-evaluation of Ba0.5Sr0.5Co0.8Fe0.2O3−δ perovskite as oxygen semi-permeable membraneJ Membr Sci, 291
V. Belousov (2010)
Electrochemical mechanism of hot corrosion of Bi2O3-deposited copperCorrosion Science, 52
A. Bunde, K. Funke, M. Ingram (1998)
Ionic glasses: History and challengesSolid State Ionics, 105
J. Blendell, W. Carter, C. Handwerker (1999)
Faceting and Wetting Transitions of Anisotropic Interfaces and Grain BoundariesJournal of the American Ceramic Society, 82
(1971)
Effect of partial pressure of steam , oxygen and temperature on the electrical properties of the liquid V 2 O 5 . Izv Akad Nauk SSSR
R. Bredesen, K. Jordal, O. Bolland (2004)
High-temperature membranes in power generation with CO2 captureChemical Engineering and Processing, 43
V. Belousov (1999)
The “catastrophic” oxidation of metalsRussian Journal of Physical Chemistry A, Focus on Chemistry, 82
J. Israelachvili (1985)
Intermolecular and surface forces
Chiang, Wang, Lee (1998)
HREM and STEM of intergranular films at zinc oxide varistor grain boundariesJournal of Microscopy, 191
J.-R. Lee, Y. Chiang, G. Ceder (1997)
Pressure-thermodynamic study of grain boundaries: Bi segregation in ZnOActa Materialia, 45
V. Belousov, S. Fedorov, I. Kulbakin (2015)
Hybrid Molten/Solid In2O3-Bi2O3 Oxygen Ion Transport MembranesJournal of Membrane Science and Research, 1
Ke-qin Huang, M. Schroeder, J. Goodenough (1999)
Oxygen Permeation Through Composite Oxide‐Ion and Electronic ConductorsElectrochemical and Solid State Letters, 2
E. Olsson, G. Dunlop (1989)
The effect of Bi2O3 content on the microstructure and electrical properties of ZnO varistor materialsJournal of Applied Physics, 66
A. Vivet, P.-M. Geffroy, E. Thune, C. Bonhomme, F. Rossignol, N. Richet, T. Chartier (2014)
New route for high oxygen semi-permeation through surface-modified dense La1−xSrxFe1−yGayO3−δ perovskite membranesJournal of Membrane Science, 454
(1993)
Apparatus for measuring the velocity and absorption of sound in the rock melts
Venkata Yarlagadda, T. Nguyen (2011)
Conductivity Measurements of Molten Bi2O3, 33
V. Belousov (1996)
Liquid‐Channel Grain‐Boundary StructuresJournal of the American Ceramic Society, 79
M. Moldover, J. Cahn (1980)
An Interface Phase Transition: Complete to Partial WettingScience, 207
R. Hunter (1987)
Foundations of Colloid Science
A review of the transport properties of molten oxide membranes (MOMs) is given. The MOMs are a new type of mixed-conducting membranes for oxygen separation from air. The rapidly expanding field of ion transport membranes is driven by a growing number of potential applications (fuel cells, membrane reactors, oxygen separators, sensors, etc.). Special attention is paid to the oxygen ion transport in MOM. The oxygen permeation kinetics and thermodynamics of MOM are considered. A dynamic polymer chain model for oxygen ion transport in molten oxides is analyzed. Prospects of MOM for oxygen technology are discussed.
Ionics – Springer Journals
Published: Feb 12, 2016
Read and print from thousands of top scholarly journals.
Already have an account? Log in
Bookmark this article. You can see your Bookmarks on your DeepDyve Library.
To save an article, log in first, or sign up for a DeepDyve account if you don’t already have one.
Copy and paste the desired citation format or use the link below to download a file formatted for EndNote
Access the full text.
Sign up today, get DeepDyve free for 14 days.
All DeepDyve websites use cookies to improve your online experience. They were placed on your computer when you launched this website. You can change your cookie settings through your browser.