Высокотемпературные протонные проводники на основе церата бария, допированного 3-d элементами
Диссертация
Для достижения высокой плотности образцов и снижения температуры спекания используются различные химические (соосаждение, глицин-нитратный, Печини) и физико-химические (криогенные, газоплазменное напыление, распылительная сушка) методы синтеза. Порошки, полученные данными методами, характеризуются высокой способностью к спеканию, но, как правило, эти методики являются трудозатратными… Читать ещё >
Список литературы
- Ishihara Т. (ed.) Perovskite Oxide for Solid Oxide Fuel CellsCells, Fuel Cells and Hydrogen Energy. Springer Dordrecht Heidelberg. London, New York. 2009.
- Чеботин B.H., Перфильев M.B. Электрохимия твёрдых электролитов. М.: Химия. 1978. 312 с.
- Camilo de Souza Е.С., Muccillo R. Properties and applications of perovskite proton conductors. Materials Research // 2010. V. 13, N 3. P. 385−394.
- Demin A.K., Tsiakaras P.E., Sobyanin V.A., Hramova. S.Yu. Thermodynamic analysis of a methane fed SOFC system based on a protonic conductor// Solid State Ionics. 2002. V. 152−153. P. 555−560.
- Shao Z., Zhou W., Zhu Z. Advanced synthesis of materials for intermediate-temperature solid oxide fuel cells // Progress in Materials Science. 2012. V. 57, N4. P. 807−874.
- Kreuer K.D. On the development of proton conducting materials for technological applications // Solid State Ionics. 1997. V. 97, N 1−4. P. 1−15.
- Hilczer-Pawotski A., Pawlaczyk Cz., Electric B. Conductivity in crystal group Me3H (Se04)2 (Me: NH+4, Rb+, Cs+) // Solid State Ionics. 1990. V. 44, N 1−2. P.17−19.
- Chowdhry U., Ochi Y., Morikawa H., Minato I., Marumo F. New inorganic proton conductors // Materials Research Bulletin. 1982. V. 17, N 7. P. 917−933.
- Naffier N., Badot J.C., Colomban Ph. Protonic conductivity of (3″ and ion-rich (3-alumina. II: Ammonium compounds // Solid State Ionics. 1984. V. 13, N3. P. 233−236.
- Takahashi Т., Iwahara H. Solid-state ionics: protonic conduction in perovskite type oxide solid solutions // Revue de Chimie Minerale. 1980. V. 17, N 4. P. 243−253.
- Iwahara H., Esaka Т., Uchida H., Maeda N. Proton conduction in sintered oxides and its application to steam electrolysis for hydrogen production // Solid State Ionics. 1981. V. 3−4. P. 359−363.
- Uchida H., Ogaki K., Iwahara H. High temperature hydrogen sensor and steam sensor using barium cerium oxide (BaCe03)-based proton conducting ceramics // Proceedings of the Electrochemical Society. 1987. V. 87−89. P. 172 179.
- Lee W.-K., Nowick A.S., Boatner L.A. Protonic conduction in acceptor-doped KTa03 crystals // Solid State Ionics. 1986. V. 18−19, N 2. P. 989−993.
- Строева А.Ю. Дефектная структура и физико-химические свойства перовскитов на основе LaSc03. Диссертация на соискание степени кандидата химических наук: 02.00.04. Екатеринбург, 2011. с. 163.
- Анимица И.Е. Высокотемпературные протонные проводники на основе перовскитоподобных сложных оксидов со структурным разупорядочением кислородной подрешетки. Диссертация на соискание степени доктора химических наук: 02.00.04. Екатеринбург, 2011. с. 296.
- Korona D.V., Neiman A.Ya. Conductivity and hydration of lanthanum-substituted barium calcium niobates Ba4. xLaxCa2Nb20ii+o.5x (x=0,5- 1- 1,5) // Russian Journal of Electrochemistry. 2011. V. 47, N 6. P. 737−747.
- Kreuer K.D. Proton-conducting oxide // Annual Review of Materials Research. 2003. V. 33. P. 333−359.
- Иванов-Шиц А.К., Мурин И. В. Ионика твердого тела, в 2 т. Том 2. СПб.: Изд-во С.-Петерб. ун-та, 2010. 1000 с.
- Hoffmann A. Zeitschrift fuer Physikalische Chemie, Abteilung В: Chemie der Elementarprozesse // Aufbau der Materie. 1935. V. 28. P. 65−77.
- Jacobson A.J., Tofield B.C., Fender B.E.F. The structures of ВаСеОз, ВаРгОз and ВаТЬОз by neutron diffraction: lattice parameter relations and ionic radii in O-perovskites // Acta Crystallographica B. 1972. V. 28. P. 956−961.
- Yamanaka S., Fujikane M., Hamaguchi T., Muta H., Oyama T., Matsuda T., Kobayashi S.-I., Kurosaki K. Thermophysical properties of BaZr03 and BaCe03 H Journal of Alloys and Compounds. 2003. V. 359, N 1−2. P. 109−113.
- Wang J.-X., Li L.-P., Campbell B. J, Lv Z., Ji Y, Xue Y.-F, Su W.-H. Structure, thermal expansion and transport properties of BaCei хЕихОз-й oxides // Materials Chemistry and Physics. 2004. V. 86, N 1. P. 150−155.
- Кузьмин A.B. Физико-химические свойства и структурные особенности цератов бария и стронция. Диссертация на соискание степени кандидата химических наук: 02.00.04. Екатеринбург, 2010. с. 139.
- Knight K.S. Structural phase transitions in ВаСеОз // Solid State Ionics. 1994. V. 74, N3−4. P. 109−117.
- A.B. Орлов, О. А. Шляхтин, А. Л. Винокуров, A.B. Кнотько, Ю. Д. Третьяков. Получение и свойства высоко дисперсных порошков ВаСеОздля низкотемпературного спекания // Неорганические материалы. 2005. Т. 41, N 11. С. 1194−1200.
- Крегер А. Химия несовершенных кристаллов. Пер. с англ. М.: Мир. 1969. 654 с.
- Wang M.-Y., Qi L.-G. Mixed Conduction in BaCe0,8Pr0,2O3s Ceramic // Chinese Journal of Chemical Physics. 2008. V. 21, N 3. P. 286−290.
- Банных A.B. Кинетика электродного процесса и транспортные свойства в системе (H2+H20+Ar), Me/BaCe,.xNdx03.a/Me, (Н2+Н20+Аг). Диссертация на соискание степени кандидата химических наук: 02.00.05. Екатеринбург, 2004. с. 216.
- Gorbova Е., Maragou V., Medvedev D., Demin A., Tsiakaras P. Investigation of the protonic conduction in Sm-doped BaCe03 // Journal of Power Sources. 2008. V.181, N 2. P. 207−213.
- Maffei N., Pelletier L., Charland J.P., McFarlan A. An ammonia fuel cell using a mixed ionic and electronic conducting electrolyte // Journal of Power Sources. 2006. V. 162. P. 165−167.
- Chen C., Ma G. Proton conduction in BaCeixGdx03-§ at intermediate temperature and its application to synthesis of ammonia at atmospheric pressure // Journal of Alloys and Compounds. 2009. V. 485, N 1−2. P. 69−72.
- Matskevich N.I., Wolf T.A. The enthalpies of formation of BaCe j хЯЕхОз й (RE = Eu, Tb, Gd) // The Journal of Chemical Thermodynamics. 2010. V. 42, N2. P. 225−228.
- Wang W.B., Liu J.W., Li Y.D., Wang H.T., Zhang F., Ma G.L. Microstructures and proton conduction behaviors of Dy-doped BaCe03 ceramics at intermediate temperature // Solid State Ionics. 2010. V. 181, N 15−16. P. 667−671.
- Wang M.-Y., Qiu L.-G., Ma G.-L. Ionic Conduction in Ba0)95Ceo, 8Hoo, 203. a // Chinese Journal of Chemistry. 2007. V. 25, N 9. P. 12 731 277.
- Yin J, Wang X, Xu J, Wang H, Zhang F, Ma G. Ionic conduction in BaCeo, 85-xZrxEro, i503. a and its application to ammonia synthesis at atmospheric pressure // Solid State Ionics. 2011. V. 185, N 1. P. 6−10.
- Qiu L.-G, Wang M.-Y. Ionic Conduction and Fuel Cell Performance of Ba0,98Ce0−8Tm0,2O3 Ceramic // Chinese Journal of Chemical Physics. 2010. V. 23, N6. P. 707−712.
- Yamaguchi S, Yamada N. Thermal lattice expansion behavior of Yb-doped BaCe03 // Solid State Ionics. 2003. V. 162−163. P. 23−29.
- Matskevich N. I, Wolf T, Matskevich M. Yu, Chupakhina T.I. Preparation, stability and thermodynamic properties of Nd- and Lu-doped BaCe03 proton-conducting ceramics // European Journal of Inorganic Chemistry. 2009. N 11. P. 1477−1482.
- Kikuchi J, Koga S, Kishi K, Saito M, Kuwano J. Ionic conductivity in lanthanoid ion-doped BaCe03 electrolytes // ECS Transactions. 2007. V. 7, N 1. P. 2283−2289.
- Coors W. G, Readey D.W. Proton conductivity measurements in yttrium barium cerate by impedance spectroscopy // Journal of the American Ceramic Society. 2002. V. 85, N 11. P. 2637−2640.
- Pelletier L, McFarlan A, Maffei N. Ammonia fuel cell using doped barium cerate proton conducting solid electrolytes // Journal of Power Sources. 2005. V. 145, N2. P. 262−265.
- Xie K, Yan R, Meng G. and Liu X. Direct ammonia proton-conducting solid oxide fuel cells prepared by a modified suspension spray // Ionics. 2009. V. 15, N l.P. 115−119.
- Li J, Luo J.-L, Chuang K. T, Sanger A.R. Chemical stability of Y-doped Ba (Ce, Zr)03 perovskites in H2S-containing H2 // Electrochimica Acta. 2008. V. 53, N10. P. 3701−3707.
- Shi Z., Luo J.-L., Wang S., Sanger A.R., Chuang K.T. Protonic membrane for fuel cell for co-generation of power and ethylene // Journal of Power Sources. 2008. V. 176, N 1. P. 122−127.
- Feng Y., Luo J., Chuang K.T. Conversion of propane to propylene in a proton-conducting solid oxide fuel cell // Fuel. 2007. V. 86, N 1−2. P. 123−128.
- Kreuer K.D. On the complexity of proton conduction phenomena // Solid State Ionics. 2000. V. 136−137. P. 149−160.
- Nowick A.S., Du Y. High-temperature protonic conductors with perovskite-related structures // Solid State Ionics. 1995. V. 77. P. 137−146.
- Kreuer K.D., Dippela Th., Baikov Yu.M., Maier J. Water solubility, proton and oxygen diffusion in acceptor doped BaCe03: A single crystal analysis // Solid State Ionics. 1996. V. 86−88, N 1. P. 613−620.
- Fabbri E., Pergolesi D., Traversa E. Materials challenges toward proton-conducting oxide fuel cells: a critical review // Chemical Society Reviews. 2010. V. 39. P. 4355−4369.
- Norby T., Wideroe M., Glockner R. and Larring Y. Hydrogen in oxides // Dalton Transactions. 2004. V. 19. P. 3012−3018.
- Taniguchi N., Hatoh K., Niikura J., Gamo T., Iwahara H. Proton conductive properties of gadolinium-doped barium cerates at high temperatures // Solid State Ionics. 1992. V. 53−56, N 2. P. 998−1003.
- Zhang C., Zhao H., Zhai S. Electrical conduction behavior of proton conductor BaCei. xSmx03.5 in the intermediate temperature range // International Journal of Hydrogen Energy. 2011. V. 36, N 5. P. 3649−3657.
- Kilner J.A. Fast oxygen transport in acceptor doped oxides // Solid State Ionics. 2000. V. 129, N 1−4 P. 13−23.
- Yashiro K., Suzuki T., Kaimai A., Matsumoto H., Nigara Y., Kawada T., Mizusaki J., Sfeir J., Van Herle J. Electrical properties and defect structure of niobia-doped ceria // Solid State Ionics. 2004. V. 175, N 1−4. P. 341−344.
- Шарова Н.В. Высокотемпературные протонные электролиты на основе церата бария. Диссертация на соискание степени кандидата химических наук: 02.00.04. Екатеринбург, 1998. с. 218.
- Amsif М, Marrero-Lopez D, Ruiz-Morales J. C, Savvin S. N, Gabas M, Nunez P. Influence of rare-earth doping on the microstructure and conductivity of ВаСе0 9Ьп01Оз-й proton conductors // Journal of Power Sources. 2011. V. 196, N 7. P. 3461−3469.
- Bonanos N, Ellis B, Knight K. S, Mahmood M.N. Ionic conductivity of gadolinium-doped barium cerate perovskites // Solid State Ionics. 1989. V. 53, N 1−2. P. 179−188.
- Шарова Н. В, Горелов В. П, Балакирева В. Б. Электроперенос в BaCe0,85Ro, i5C)3-A (R=Sm, Pr, Tb) в окислительных и восстановительных атмосферах // Электрохимия. 2005. Т. 41, N 6. С. 748−754.
- Ricote S, Caboche G, Estournes C, Bonanos N. Synthesis, sintering, and electrical properties of BaCe0,9-xZrxYo-i03-§ // Journal of Nanomaterials. 2008. V. 2008. Article ID 354 258. 5 pages, doi: 10.1155/2008/354 258.
- Bonanos N. and Willy Poulsen F. Considerations of defect equilibria in high temperature protonconducting cerates // Journal of Materials Chemistry. 1999. V. 9. P. 431−434.
- Ryu K.H., Haile S.M. Chemical stability and proton conductivity of doped BaCe03-BaZr03 solid solutions // Solid State Ionics. 1999. V. 125, N 1−4. P. 355−367.
- Oliveira A., Hafsaoui J., Hochepied J.-F., Berger M.-H., Thorel A. Synthesis of BaCe03 and BaCe0,9Yo, i03-§ from mixed oxalate precursors // Journal of the European Ceramic Society. 2007. V. 27, N 13−15. P. 3597−3600.
- Chen F., Sorensen O.T., Meng G., Peng D. Preparation of Nd-doped barium cerate through different routes // Solid State Ionics. 1997. V. 100, N 1−2. P. 63−72.
- Lee D.W., Won J.H., Shim K.B. Low temperature synthesis of BaCe03 nanopowders by the citrate process // Materials Letters. 2003. V. 57, N 22−23. P. 3346−3351.
- Khani Z., Taillades-Jacquin M., Taillades G., Marrony M., Jones D.J., Roziere J. New synthesis of nanopowders of proton conducting materials. A route to densified proton ceramics // Journal of Solid State Chemistry. 2009. V. 182, N 4. P. 790−798.
- Chakroborty A., Sharma A.D., Maiti B., Maiti H.S. Preparation of low-temperature sinterable BaCe0,8Sm0i2O3 powder by autoignition technique // Materials Letters. 2002. V. 57, N 4. P. 862−867.
- Giannici F., Longo A., Deganello F., Balerna A., Arico A.S., Martorana A. Local environment of Barium, Cerium and Yttrium in BaCei-xYx03s ceramic protonic conductors // Solid State Ionics. 2007. V. 178, N 7−10. P. 587−591.
- Bi L., Zhang S., Fang S., Zhang L., Xie K., Xia C., Liu W. Preparation of an extremely dense BaCe0.8Sm0.2O3−5 thin membrane based on an in situ reaction // Electrochemistry Communications. 2008. V. 10, N 7. P. 1005−1007.
- Bi L., Zhang S., Lin B., Fang S., Xia C., Liu W. Screen-printed BaCe () 8Smo 203-S thin membrane solid oxide fuel cells with surface modification by spray coating // Journal of Alloys and Compounds. 2009. V. 473, N 1−2. P. 4852.
- Kleinlogel C., Gauckler L.J. Sintering and properties of nanosized ceria solid solutions // Solid State Ionics. 2000. V. 135, N 1−4. P. 567−573.
- Fagg D.P., Abrantes J.C.C., Perez-Coll D., Nunez P., Kharton V.V., Frade J.R. The effect of cobalt oxide sintering aid on electronic transport in Ce0,8oGdo, 2o02−8 electrolyte // Electrochimica Acta. 2003. V. 48, N 5. P. 1023−1029.
- Han M.-F., Zhou S., Liu Z., Lei Z., Kang Z.-C. Fabrication, sintering and electrical properties of cobalt oxide doped Gd0-iCe0,9O2-s // Solid State Ionics. 2011. V. 192, N l.P. 181−184.
- Pikalova E.Yu., Maragou V.I., Demin A.K., Murashkina A.A., Tsiakaras P.E. Synthesis and electrophysical properties of (l-x)Ce0,8Gdo, 202s+xTi02 (x=0−0.06) solid-state solutions // Solid State Ionics. 2008. V. 179, N 27−32. P. 15 571 561.
- Yang C.-F. and Lo S.-H. Grain growth for CuO-BaO mixtures added BaTi1+x03+2x ceramics. // Materials Research Bulletin. 1997. V. 32, N 12. P. 17 131 722.
- Roth R. S, Davis K. L, Dennis J.R. Phase equilibria and crystal chemistry in the system Ba-Y-Cu-0 // Advanced Ceramic Materials. 1987. V. 2, N 3B. P. 303−312.
- Arjomand M, Machin D.J. Oxide chemistry. Part II. Ternary oxides containing copper in oxidation states -I, -II, -III, and -IV // Journal of the Chemical Society. Dalton Transaction. 1975. V.ll. P. 1061−1066.
- Klinkova L. A, Nikolaichik V. I, Barkovskii N. V, Fedotov V.K. New Phases in the barium rich region of the Ba0-BaCu02 system // Bulletin of the Russian Academy of Sciences: Physics. 2009. V.73, N 8. P. 1104−1106.
- Klinkova L. A, Nikolaichik V. I, Barkovskii N. V, Fedotov V.K. On the existence of a homologous series of BamCum+nOy oxides with the cubic structure of the BaCu02 oxide // Physica C: Superconductivity. 2010. V. 470, N 22. P. 20 672 071.
- Zhang W, Osamura K, Ochiai S. Phase diagram of the BaO-CuO binary system // Journal of American Ceramic Society. 1990. V. 73, N 7. P. 1958−1964.
- Yim D. K, Kim J.-R, Kim D.-W, Hong K.S. Microwave dielectric properties and low-temperature sintering of Ba3Ti4Nb402i ceramics with B203 and CuO additions // Journal of the European Ceramic Society. 2007. V. 27, N 8−9. P. 3053−3057.
- Chou C.-S, Liu C.-L, Hsiung C.-M, Yang R.-Y. Preparation and characterization of the lead-free piezoelectric ceramic of Bi0 5Na0>5TiO3 doped with CuO // Powder Technology. 2011. V. 210, N 3. P. 212−219.
- Cho K.-H, Lim J.-B, Nahm S, Kim H.-T, Kim J.-H, Paik J.-H, Lee H.-J. Low temperature sintering of Ba0-Sm203−4Ti02 ceramics // Journal of the European Ceramic Society. 2007. V. 27, N 2−3. P. 1053−1058.
- Liou Y.-C, Wu C.-T, Huang Y.-L, Chung T.-C. Effect of CuO on CaTi03 perovskite ceramics prepared using a direct sintering process // Journal of Nuclear Materials. 2009. V. 393, N 4. P. 492−496.
- Dong Y, Hampshire S, Zhou J.-E, Meng G. Synthesis and sintering of Gd-doped Ce02 electrolytes with and without 1 at.% CuO doping for solid oxide fuel cell applications // International Journal of Hydrogen Energy. 2011. V. 36, N 8. P. 5054−5066.
- Zhang T, Hing P, Huang H, Kilner J. Sintering and grain growth of CoO-doped Ce02 ceramics // Journal of the European Ceramic Society. 2002. V. 22, N 1. P. 27−34.
- Dong Y, Hampshire S, Zhou J.-E, Dong X, Lin B, Meng G. Mechanical strengthening of Sm-doped Ce02 ceramics by 1 mol.% cobalt oxide for solid oxide fuel cell application // Journal of Power Sources. 2011. V, 196, N 20. P. 8402−8405.
- Zhang T. S, Du Z. H, Li S, Kong L. B, Song X. C, Lu J, Ma J. Transitional metal-doped 8 mol% yttria-stabilized zirconia electrolytes // Solid State Ionics. 2009. V. 180, N 23−25. P. 1311−1317.
- Shimura T, Tanaka H. I, Matsumoto H, Yogo T. Influence of the transition-metal doping on conductivity of a BaCe03-based protonic conductor // Solid State Ionics. 2005. V. 176, N 39−40. P. 2945−2950.
- Azimova M. A, Mcintosh S. Transport properties and stability of cobalt doped proton conducting oxides // Solid State Ionics. 2009. V. 180, N 2−3. P. 160 167.
- Azimova M.A. and Mcintosh S. Properties and performance of anode-supported proton-conducting BaCe0 4XZr ().4Yb0jCo002OrSolid oxide fuel cells // Journal of The Electrochemical Society. 2010. V. 157, N 10. P. B1397-B1402.
- Ricote S., Bonanos N. Enhanced sintering and conductivity study of cobalt or nickel doped solid solution of barium cerate and zirconate // Solid State Ionics. 2010. V. 181, N 15−16. P. 694−700.
- Zhang T.S., Chan S.H., Kong L.B., Sheng P.T., Ma J. Synergetic effect of NiO and Si02 on the sintering and properties of 8 mol% yttria-stabilized zirconia electrolytes // Electrochemica Acta. 2009. V. 54, N 3. P. 927−934.
- Babilo P. and Haile S.M. Enhanced sintering of yttrium-doped barium zirconate by addition of ZnO // Journal of American Ceramic Society. 2005. V. 88, N9. P. 2362−2368.
- Azad A.K. High density and low temperature sintered proton conductor BaCe055Zr0,35Sc0,iZn0,05O38 // Solid State Ionics. 2008. V. 179, N 19−20. P. 678 682.
- Xie K., Yan R., Liu X. A novel anode supported BaCeo^Zro^Sno.i Y0.2O3 8 electrolyte membrane for proton conducting solid oxide fuel cells // Electrochemistry Communications. 2009. V. 11, N 8. P. 1618−1622.
- Wang H., Peng R., Wu X., Hu J., Xia C. Sintering behavior and conductivity study of yttrium-doped BaCe03-BaZr03 solid solutions using ZnO additives // Journal of the American Ceramic Society. 2009. V. 92, N 11. P. 26 232 629.
- Tao S, Irvine J.T.S. A stable, easily sintered proton-conducting oxide electrolyte for moderate-temperature fuel cells and electrolyzers // Advanced Materials. 2006. V. 18, N 12. P. 1581−1584.
- Tsipis E. V, Kharton V.V. Electrode materials and reaction mechanisms in solid oxide fuel cells: a brief review. I. Performance-determining factors // Journal of Solid State Electrochemistry. 2008. V. 12, N 9. P. 1039−1060.
- Tsipis E. V, Kharton V.V. Electrode materials and reaction mechanisms in solid oxide fuel cells: a brief review. II. Electrochemical behavior vs. materials science aspects // Journal of Solid State Electrochemistry. 2008. V. 12, N 11. P. 1367−1391.
- Tsipis E. V, Kharton V.V. Electrode materials and reaction mechanisms in solid oxide fuel cells: a brief review. III. Recent trends and selected methodological aspects // Journal of Solid State Electrochemistry. 2011. V. 15, N5. P. 1007−1040.
- Tolchard J, Grande T. Physicochemical compatibility of SrCe03 with potential SOFC cathodes // Journal of Solid State Chemistry. 2007. V. 180, N 10. P. 2808−2815.
- Кузин Б. Л, Перфильев M. B, Горелов В. П, Береснев С. М, Клещев Ю. Н. Топливный элемент с твердым электролитом на основе ВаСеОз и электродами из неблагородных материалов // Электрохимия. 1997. Т. 33, N 12. С. 1475−1479.
- Li N" Lu Z, Wei B" Huang X, Chen K, Zhang Y, Su W. Characterization of GdBaCo205+8 cathode for IT-SOFCs // Journal of Alloys and Compounds. 2008. V. 454, N 1−2. P. 274−279.
- Zhou Q., He Т., Ji Y. SmBaCo205 +x double-perovskite structure cathode material for intermediate-temperature solid-oxide fuel cells // Journal of Power Sources. V. 185, N 12. P. 754−758.
- Zhao L., He В., Xun Z., Wang H., Peng R., Meng G., Liu X. Characterization and evaluation of NdBaCo205+5 cathode for proton-conducting solid oxide fuel cells // International Journal of Hydrogen Energy. 2010. V. 35, N2. P. 753−756.
- Lee S.J., Kim D.S., Kim D.K. High-performance GdBaCo205+5-Ce0−9Gdo, iOi-95 composite cathode for solid oxide fuel cells // Current Applied Physics. 2011. V. 11, N 1. P. S238-S241.
- Рорелов В.П., Балакирева В. Б., Шарова H.B., Валенцев А. В., Клещев Ю. Н., Брусенцов В. П. Исследование стабильности керамики BaCeNd03: и ее электрофизических свойств. Электронный ресурс. http://toc.vniitf.ru/01 ru/papers/12.htm.
- Xie К., Yan R., Xu X., Liu X., Meng G. A stable and thin BaCeo, 7Nbo, iGdo, 203. s membrane prepared by simple all-solid-state process for SOFC // Journal of Power Sources. 2009. V. 187, N 2. P. 403−406.
- Yan R., Wang Q., Xie K. A stable and easily sintering BaCe0,7Sn0,iGd0,2O3 s electrolyte for solid oxide fuel cells // Ionics. 2009. V. 15, N 4. P. 501−505
- Xie K., Yan R, Chen X., Wang S., Jiang Y., Liu X., Meng G. A stable and easily sintering BaCe03-based proton-conductive electrolyte // Journal of Alloys and Compounds. 2009. V. 473, N 1−2. P. 323−329.
- Pasierb P., Drozdz-Ciesla E., Gajerski R., Labus S. and Komornicki S. Chemical stability of Ba (Cei-xTix)1yYy03 proton-conducting solid electrolytes // Journal of Thermal Analysis and Calorimetry. 2009. V. 96, N 2. P. 475−480.
- Yan R., Wang Q., Chen G., Huang W., Xie K. A stable BaCe03-based proton conductor for solid oxide fuel cells // Ionics. 2009. V. 15, N 6. P. 749−752.
- Tao Z, Zhu Z, Wang H, Liu W. A stable BaCe03-based proton conductor for intermediate-temperature solid oxide fuel cells // Journal of Power Sources. 2010. V. 195, N 11. P. 3481−3484.
- Kreuer K.D. Aspects of the formation and mobility of protonic charge carriers and the stability of perovskite-type oxides // Solid State Ionics. 1999. V. 125, N4. P. 285−302.
- Bonanos N, Knight K. S, Ellis B. Perovskite solid electrolytes: structure, transport properties and fuel cell applications // Solid State Ionics. 1995. V. 79. P. 161−170.
- Медведев Д. А, Горбова E. B, Демин A. K, Антонов Б. Д. Структура и электрические свойства BaCe0,77-xZrxGdo, 2Cuo, o303−5 Н Электрохимия. 2011. Т. 47, N 12. С. 1504−1510.
- Lu J, Wang L, Fan L, Li Y, Dai L, Guo H. Chemical stability of doped BaCe03-BaZr03 solid solutions in different atmospheres // Journal of Rare Earth. 2008. V. 26, N 4. P. 505−510.
- Guo Y, Lin Y, Ran R, Shao Z. Zirconium doping effect on the performance of proton-conducting В aZ г y С e Y о, 2 О 3 й (0,0
- Lv J, Wang L, Lei D, Guo H, Kumar R.V. Sintering, chemical stability and electrical conductivity of the perovskite proton conductors BaCe0,45Zr0,45M0jiO3−5 (M = In, Y, Gd, Sm) // Journal of Alloys and Compounds.2009. V. 476, N 1−2. P. 376−382.
- Li N, Wei В., Lu Z" Huang X, Su W. GdBaCozOs+s-Smo^Ceo^O,^ composite cathodes for intermediate temperature SOFCs // Journal of Alloys and Compounds. 2011. V. 509, N 8. P. 3651−3655.
- Guo Y., Ran R., Shao Z. Fabrication and performance of a carbon dioxide-tolerant proton-conducting solid oxide fuel cells with a dual-layer electrolyte // International Journal of Hydrogen Energy. 2010. V. 35, N 19. P. 10 513−10 521.
- Yang L., Zuo C., Liu M. High-performance anode-supported solid oxide fuel cells based on Ba (Zr0,iCe0,7Yo, 2)03−5 (BZCY) fabricated by a modified co-pressing process // Journal of Power Sources. 2010. V. 195, N. P. 1845−1848.
- ГОСТ 2409–95. Огнеупоры. Метод определения кажущейся плотности, открытой и общей пористости, водопоглощения.141 http://zirconiaproject.wordpress.com/devices/zirconia-318.
- Мищенко К.П., Равдель А. А. Краткий справочник физико-химических величин. JL: Химия. 1974. 200 с.
- Kikuchi J., Koga S., Kishi К., Saito M., Kuwano J. Composite and oxygen-ion conductivity of BaCe03-based electroclytes // Key Engineering Materials. 2007. V. 350. P. 179−182.
- Knight K.S., Bonanos N. Space group and lattice constants for barium cerate and minor corrections to the crystal structures of BaCe0,9Y0,iO2−95 and BaCeo, 9Gdo, i02,95 H Journal of Material Chemistry. 1994. V. 4, N 6. P. 899−901.
- Maffei N, Pelletier L, Charland J. P, and McFarlan A. A direct ammonia fuel cell using barium cerate proton conducting electrolyte doped with gadolinium and praseodymium // Fuel Cells. 2007. V. 7, N 4. P. 323−328.
- Kai J, Zhiqi H, Jian M, Yufang R. and Qiang S. Low temperature preparation and fuel cell properties of rare earth doped barium cerate solid electrolytes // Science in China (B). 1999. V. 42, N 3. P. 298−304.
- Gorbova E, Maragou V, Medvedev D, Demin A, Tsiakaras P. Influence on Cu in the properties of gadolinium-doped barium cerate // Journal of Power Sources. 2008. V. 181, N 2. P. 207−213.
- Pintar L, Batista J, Hocevar S. Nanostructured CuxCei-x02-y mixed oxide catalysts: characterization and WGS activity tests // Journal of Colloid and Interface Science. 2007. V. 307, N 1. P. 145−157.
- Богданович H. M, Горелов В. П, Балакирева В. Б, Демьяненко Т. А. Влияние меди на свойства твердых электролитов (Ce0,8Sm0>2)i-xCuxO2-A гкомпозиционных катодов на основе Гао^ГсцМпОз // Электрохимия. 2005. Т. 41, N5. С. 656−661.
- Shannon R.D. Revised effective ionic radii and systematic studies of interatomic distances in halides and chalcogenides // Acta Crystallographica. 1976. V. A32.P. 751−767.
- Kim S.S. Thermodynamic modeling of the Ce02-CoO phase diagram // Journal of Alloys and Compounds. V. 390, N 1−2. P. 223−225.
- Costa R, Griinbaum N, Berger M.-H, Dessemond L, Thorel A. On the use of NiO as sintering additive for BaCe0−9Yo |03(i // Solid State Ionics. 2009. V. 180, 11−13. P. 891−895.
- Tong J, Clark D, Hoban M, O’Hayre R. Cost-effective solid-state reactive sintering method for high conductivity proton conducting yttrium-doped barium zirconium ceramics // Solid State Ionics. V. 181, N 11−12. P. 496−503.
- Amsif M., Marrero-Lopez D., Ruiz-Morales J.C., Savvin S.N., Nunez P. Effect of sintering aids on the conductivity of BaCe0,9Ln0,iO3-s // Journal of Power Sources. V. 196, N 22. P. 9154−9163.
- Taniguchi N. Mixed ionic conductor and device using the same. Patent No.: US 6,528,195 Bl. 2003.
- Gao D., Guo R. Structural and electrochemical properties of yttrium-doped barium zirconate by addition of CuO // Journal of Alloys and Compounds. 2010. V. 493, N 1−2. P. 288−293.
- Maffei N., Pelletier L., McFarlan A. Performance characteristics of Gd-doped barium cerate-based fuel cells // Journal of Power Sources. 2004. V. 136, N l.P. 24−29.
- Wang M., Qiu L., Sun Y. Ionic conduction in ВахСео.8Рг (К20за// Journal of rare earth. 2009. V. 27, N 5. P. 819−824.
- Lewis G.S., Atkinson A. and Steele B.C.H. Cobalt additive for lowering the sintering temperature of yttria-stabilized zirconia // Journal of Materials Science Letters. 2001. V 20, N 12. P. 1155−1157.
- Jud E., Gauckler L.J. Sintering behavior of cobalt oxide doped ceria powders of different particle sizes // Journal of Electroceramics. 2005. V. 14, N 3. P. 247−253.
- Yan R., Chu F., Ma Q., Liu X., Meng G. Sintering kinetics of samarium doped ceria with addition of cobalt oxide // Materials Letters. 2006. V. 60, N 2930. P. 3605−3609.
- Tong J., Clark D., Bernau L., Subramaniyan A., O’Hayre R. Proton-conducting yttrium-doped barium cerate ceramics synthesized by a cost-effective solid-state reactive sintering method // Solid State Ionics. 2010. V. 181, N 33−34. P. 1486−1498.
- Пикалова Е.Ю., Демина A.H., Демин A.K., Мурашкина А. А., Соперников В. Е., Есина Н. О. Влияние добавок Со2Оэ, ТЮ2, Fe2Q3, Мп203 насвойства Ce0,8Gdo, 202−5 11 Неорганические материалы. 2007. Т. 43, N 7. С. 830−837.
- Ricote S, Bonanos N, Wang H. J, Haugsrud R. Conductivity, transport number measurements and hydration thermodynamics of BaCeo, 2Zro, 7Y (o, b0Ni^O (3−5) // Solid State Ionics. 2011. V. 185, N 1. P. 11−17.
- German R. M, Suri P, Park S.J. Review: liquid phase sintering // Journal of Material Science. 2009. V. 44, N 1. P. 1−39.
- Fabbri E, Bi L, Pergolesi D, Traversa E. Towards the next generation of solid oxide fuel cells operating below 600 °C with chemically stable proton-conducting electrolytes // Advanced Materials. 2011. V. 24, N 2. P. 195−208.
- Iguchi F, Tsurui T, Sata N, Nagao Y, Yugami H. The relationship between chemical composition distributions and specific grain boundary conductivity in Y-doped BaZr03 proton conductors // Solid State Ionics. V. 180, N 6−8. P. 563−568.
- Ricote S, Bonanos N, Caboche G. Water vapour solubility and conductivity study of the proton conductor BaCe (o, 9 x) ZrxYojO (3 // Solid State Ionics. 2009. V. 180, N 14−16. P. 990−997.
- Paria M. K, Maiti H.S. Electrical conduction in barium cerate doped with M203 (M=La, Nd, Ho) // Solid State Ionics. 1984. V. 13, N 4. P. 285−292.
- Stevenson D.A., Jiang N., Buchanan R.M., Henn F.E.G. Characterization of Gd, Yb and Nd doped barium cerates as proton conductors // Solid State Ionics. 1993. V. 62, N 3−4. P. 279−285.
- Shirpour M. Grain boundary characterization of electroceramics: Acceptor-doped BaZr03, an intermediate temperature proton conductor. PhD thesis. 2011. Stuttgart, Germany.
- Medvedev D., Maragou V., Zhuravleva Т., Demin A., Gorbova E., Tsiakaras P. Investigation of the structural and electrical properties of Co-doped BaCe0,9Gd0,O3V/ Solid State Ionics. 2011. V. 182, N 1. P. 41−46.
- Lewis G.S., Atkinson A., Steele B.C.H., Drennan J. Effect of Co addition on the lattice parameter, electrical conductivity and sintering of gadolinia-doped ceria // Solid State Ionics. 2002. V.152−153. P. 567−573.
- Шарова H.B., Горелов В. П. Электропроводность и ионный перенос в твердых электролитах ВаСео^КолэОз-б (R=P3E) // Электрохимия. 2003. Т.39, N 5. С.513−518.
- Shimura Т., Esaka К., Matsumoto Н., Iwahara Н. Protonic conduction in Rh-doped AZr03 (A=Ba, Sr and Ca) // Solid State Ionics. 2002. V. 149, N 3−4. P. 237−246.
- Wang M., Qiu L., Zhang T. Chemical stability and electrical property of BaCeo, 7Zr0)2Ndo, i03-a ceramic // Chinese Journal of Chemistry. 2010. V. 28, N 7. P. 1121−1125.
- Duval S.B.C., Holtappels P., Stimming U., Graule T. Effect of minor element addition on the electrical properties of BaZr0,9Y0-iO3-s// Solid State Ionics. 2008. V. 179, N21−26. P. 1112−1115.
- Yang L, Wang S, Lou X, Liu M. Electrical conductivity and electrochemical performance of cobalt-doped BaZr0, CeojYo^O^-s cathode // International Journal of Hydrogen Energy. 2011. V. 36, N 3. P. 2266−2270.
- Song S.-J, Wachsman E. D, Dorris S. E, Balachandran U. Defect chemistry modeling of high-temperature proton-conducting cerates // Solid State Ionics. 2002. V. 149, N. P. 1−10.
- Uchida H, Maeda N, Iwahara H. Relation between proton and hole conduction in SrCeCVbased solid electrolytes under water-containing atmospheres at high temperatures // Solid State Ionics. 1983. V. 11, N 2. P. 117−124.
- Song S.-J, Wachsman E. D, Dorris S. E, Balachandran U. Electrical Properties of p-Type Electronic defects in the protonic conductor SrCe0,95Eu0,05O3§ // Journal of Electrochemical Society. 2003. V. 150, N 6. P. A790-A795.
- Schober T, Schilling W, Wcnzl H. Defect model of proton insertion into oxides // Solid State Ionics. 1996. V. 86−88, N 1. P. 653−658.
- He. T, Ehrhat P. An optical in-situ study of ВаСеОз at high temperatures // Solid State Ionics. 1996. V. 86−88. P. 633−638.
- Virkar A.N. and Maiti H.S. Oxygen ion conduction in pure and yttria-doped barium cerate // Journal of Power Sources. 1985. V. 14, N. P. 295−303.
- Горелов В. П, Шарова H. B, Соколова Ю. В. Электропроводность электролитов Ba (Ce0,85Ro, 15)3−5 (R-редкоземельный элемент) в восстановительной водородсодержащей атмосфере // Электрохимия. 1997. Т. 33, N 12. С. 1455−1460.
- Антонова Е. П, Ярославцев И. Ю, Бронин Д. И, Балакирева В. Б, Горелов В. П, Цидильковский В. И. Особенности электропереноса и изотопные эффекты H/D в протонпроводящем оксиде BaZr0,9Y0,iO3s // Электрохимия. 2010. V. 46, N 7. Р. 792−799.
- Lim D.-K., Park C.-J., Choi M.-B., Park C.-N., Song S.-J. Partial conductivities of mixed conducting BaCeo^sZro^YojsC^ // International Journal of Hydrogen Energy. 2010. V. 35, N 19. P. 10 624−10 629.
- Sun C., Hui R., Roller J. Cathode materials for solid oxide fuel cells: a review // Journal of Solid State Electrochemistry. 2010. V. 14, N 7. P. l 125−1144.
- Cowin P.I., Petit C.T.G., Lan R., Irvine J.T.S., Tao S. Recent progress in the development of anode materials for solid oxide fuel cells // Advanced Energy Materials. 2011. V. 1, N 3. P. 314−332.
- Guo Y., Ran R., Shao Z. A novel way to improve performance of proton-conducting solid-oxide fuel cells through enhanced chemical interaction of anode components // International Journal of Hydrogen Energy. 2011. V. 36, N 2. P. 1683−1691.
- Bia L., Tao Z., Liu C., Sun W., Wang H., Liu W. Fabrication and characterization of easily sintered and stable anode-supported proton-conducting membranes // Journal of Membrane Science. 2009. V. 336, N 1−2. P. 1−6.
- Essoumhi A., Taillades G., Taillades-Jacquin M., Jones D.J., Roziere J. Synthesis and characterization of Ni-cermet/proton conducting thin film electrolyte symmetrical assemblies // Solid State Ionics. 2008. V. 179, N 38. P. 2155−2159.
- Zhou Q., Wang F., Shen Y., He T. Performances of LnBaCo205+5-Ce0.8Sm0,2OK9 composite cathodes for intermediate-temperature solid oxide fuel cells // Journal of Power Sources. 2010. V. 195, N 8. P. 2174−2181.
- Zhu С, Liu X, Yi С, Pei L" Wang D, Yan D, Yao K, Lu T, Su W. High-performance PrBaCo205lS-Ceo8Smu201i9 composite cathodes for intermediate temperature solid oxide fuel cell // Journal of Power Sources. 2010. V. 195, N 11. P. 3504−3507.
- Wu T, Peng R, Xia C. Sm0,5Sro55Co03−5-BaCeo, 8Smo, 2035 composite cathodes for proton-conducting solid oxide fuel cells // Solid State Ionics. 2008. V. 179, N27−32. P. 1505−1508.
- Медведев Д. А, Журавлева Т. А, Мурашкина А. А, Сергеева B.C., Антонов Б. Д. Электрофизические свойства материалов на основе BaGdCo205+8 // Журнал физической химии. 2010. Т. 84, N 9. С. 1777−1781.
- Beckel D, Bieberle-Hutter A, Harvey A, Infortuna A, Muecke U. P, Prestat M, Rupp J.L.M, Gauckle L.J. Thin films for micro solid oxide fuel cells // Journal of Power Sources. 2007. V. 173, N 1. P. 325−345.
- Kuhn M, Napporn T.W. Single-chamber solid oxide fuel cell technology-from its origins to today’s state of the art // Energies. 2010. V. 3, N 1. P.57−134.
- Zunic M, Chevallier L, DiBartolomeo E, D’Epifanio A., Licoccia S, Traversa E. Anode supported protonic solid oxide fuel cells fabricated using electrophoretic deposition // Fuel Cells. 2011. V. 11, N 2. P. 165−171.
- Qiu L.-G, Ma G.-L, Wen D.-J. Properties and application of ceramic ВаСео, 8Ноо, 2Оз. а // Chinese Journal of Chemistry. 2005. V. 23, N 12. P. 16 411 645.
- Qiu L.-G, Wang M.-Y. Ionic Conduction and Fuel Cell Performance of Ва0,98Се0,8Тт0−2Оз.а // Chinese Journal of Chemical Physics. 2010. V. 22, N 6. P. 707−712.
- Wu X., Wang H., Peng R., Xia C., Meng G. Effect of A-site deficiency in BaCeo, 8Smo, 203-s on the electrode performance for proton conducting solid oxide fuel cells// Solid State Ionics. 2011. V. 192, N 1. P. 611−614.
- Zhao L., He B., Ling Y., Xun Z., Peng R, Meng G. X. Liu Cobalt-free oxide Bao, 5Sr0−5Feo, 8Cuo, 2038 for proton-conducting solid oxide fuel cell cathode // International Journal of Hydrogen Energy. 2010. V. 35, N 8. P. 3769−3774.
- Ding H., Xue X., Liu X., Meng G. High performance protonic ceramic membrane fuel cells (PCMFCs) with Sm0.5Sr0.5CoC>35 perovskite cathode // Journal of Alloys and Compounds. 2010. V. 494, N 1−2. P. 233−235.