Диссертация (Перовскитоподобные материалы на основе переходных и редкоземельных металлов закономерности химической и термической стабильности), страница 49
Описание файла
Файл "Диссертация" внутри архива находится в папке "Перовскитоподобные материалы на основе переходных и редкоземельных металлов закономерности химической и термической стабильности". PDF-файл из архива "Перовскитоподобные материалы на основе переходных и редкоземельных металлов закономерности химической и термической стабильности", который расположен в категории "". Всё это находится в предмете "химия" из Аспирантура и докторантура, которые можно найти в файловом архиве СПбГУ. Не смотря на прямую связь этого архива с СПбГУ, его также можно найти и в других разделах. , а ещё этот архив представляет собой докторскую диссертацию, поэтому ещё представлен в разделе всех диссертаций на соискание учёной степени доктора химических наук.
Просмотр PDF-файла онлайн
Текст 49 страницы из PDF
– 2013. – V. 49. – P. 645-651.197. Hu Y., Bouffanais Y., Almar L., Moratab A., Tarancon A., Dezanneau G. La2–xSrxCoO4–(x = 0.9, 1.0, 1.1) Ruddlesden–Popper–type layered cobaltites ascathode materials for IT–SOFC application // Int. J. Hydrogen Energy.
– 2013. –V. 38. – P. 3064-3072.198. Sase M., Yashiro K., Sato K., Mizusaki J., Kawada T., Sakai N., Yamaji K.,Horita T., Yokokawa H. Enhancement of oxygen exchange at the hetero interfaceof (La,Sr)CoO3/(La,Sr)2CoO4 in composite ceramics // Solid State Ionics. – 2008. –V. 178. – P. 1843-1852.199. Fryburg G.C., Kohl F.J., Stearns C.A. Enhanced oxidative vaporization of Cr2О3and chromium by oxygen atoms // J. Electrochem.
Soc.: Solid–State Science andTechnology. – 1974. – V. 121. – P. 952-959.200. Ebbinghaus B.B. Thermodynamics of gas phase chromium species: thechromium oxides, the chromium oxyhydroxides, and volatility calculations inwaste incineration processes // Combust. Flame. – 1993.
– V. 93. – P. 119-137.294201. Hilpert K., Das D., Miller M., Peck D.H., Weiss R. Chromium vapor speciesover solid oxide fuel cell interconnect materials and their potential for degradationprocesses // J. Electrochem. Soc. – 1996. – V. 143. – P. 3642-3647.202. Jacobson N., Myers D., Opila E., Coplan E. Interactions of water vapor withoxides at elevated temperatures // J. Phys. Chem.
Solids. – 2005. – V. 66. – P. 471478.203. Opila E.J., Myers D.L., Jacobson N.S., Nielsen I.M.B., Johnson D.F., OlminskyJ.K., Allendorf M.D. Theoretical and experimental investigation of thethermochemistry of CrO2(OH)2(g) // J. Phys. Chem. A. – 2007. – V. 111. – P.1971-1980.204.
Taniguchi S., Kadowaki M., Kawamura H., Yasuo T., Akiyama Y., Miyake Y.,Saitoh T. Degradation phenomena in the cathode of a solid oxide fuel cell with analloy separator // J. Power Sources. – 1995. – V. 55. – P. 73-79.205. Badwal S.P.S., Deller R., Foger K., Ramprakash Y., Zhang J.P. Interactionbetween chromia forming alloy interconnects and air electrode of solid oxide fuelcells // Solid State Ionics.
– 1997. – V. 99. – P. 297-310.206. Matsuzaki Y., Yasuda I. Dependence of SOFC cathode degradation bychromium–containing alloy on compositions of electrodes and electrolytes // J.Electrochem. Soc. – 2001. – V. 148. – P. A126-A131.207. Jiang S.P. A comparison of O2 reduction reactions on porous (La,Sr)MnO3 and(La,Sr)(Co,Fe)O3 electrodes // Solid State Ionics. – 2002. – V. 146. – P. 1-22.208.
Komatsu T., Arai H., Chiba R., Nozawa K., Arakawa M., Sato K. Cr poisoningsuppression in solid oxide fuel cells using LaNi(Fe)O3 electrodes // Electrochem.Solid-State Lett. – 2006. – V. 9. – P. A9-A12.209. Komatsu T., Chiba R., Arai H., Arakawa M., Sato K. Chemical compatibilityand electrochemical property of intermediate–temperature SOFC cathodes underCr poisoning condition // J. Power Sources. – 2008.
– V. 176. – P. 132-137.210. Yokokawa H., Horita T., Sakai N., Yamaji K., Brito M.E., Xiong Y.P.,Kishimoto H. Thermodynamic considerations on Cr poisoning in SOFC cathodes //Solid State Ionics. – 2006. – V. 177. – P. 3193-3198.295211. Schuler J.A., Yokokawa H., Calderone C.F., Jeangros Q., Wuillemin Z.,Hessler–Wyser A., Van herle J. Combined Cr and S poisoning in solid oxide fuelcell cathodes // J.
Power Sources. – 2012. – V. 201. – P. 112-120.212. JANAF Thermochemical Tables, Part I. Third Edition. Eds.: M.W. Chase, C.A.Davies, J.R. Downey, D.J. Frurip, R.A. McDonald, N. Syverud. – New York:American Institute of Physics, 1986.213. IVTANTHERMO – A thermodynamic database and software system for thecomputer. Eds.: V.S. Yungman, V.A. Medvedev, I.V. Veits, G.A. Bergman. –Boca Raton: CRC Press/Begell House, 1993.214. Thermodynamic database MALT group. Thermodynamic database MALT forWindows.
Kagaku Gijutsu-Sha, 2005. http://www.kagaku.com/malt/index.html.215. Шефер Г. Химические транспортные реакции. – Москва: Мир, 1964. – 189с.216. Gindorf C., Hilpert K., Nabielek H., Singheiser L., Ruckdäschel R., Schiller G.,Chromium release from metallic interconnects with and without coatings. //Proceedings of the 4th European SOFC Forum. Ed. J.
McEvoy. Oberrohrdorf.Switzerland. – 2000. – V. 2. – P. 845-854.217. Gindorf C., Singheiser L., Hilpert K. Chromium vaporisation from Fe, Cr basealloys used as interconnect in fuel cells // Steel Research. – 2001. – V. 72. – P.528-533.218. Collins C., Lucas J., Buchanan T.L., Kopczyk M., Kayani A., Gannon P.E.,Deibert M.C., Smith R.J., Choi D.S., Gorokhovsky V.I. Chromium volatility ofcoated and uncoated steel interconnects for SOFCs // Surf. Coat.
Technol. – 2006.– V. 201. – P. 4467-4470.219. Casteel M., Lewis D., Wilson P., Alinger M. Ionic conductivity method formeasuring vaporized chromium species from solid oxide fuel cell interconnects //Int. J. Hydrogen Energy. – 2012. – V. 37. – P. 6818-6829.220. Sachitanand R., Sattari M., Svensson J.E., Froitzheim J. Evaluation of theoxidation and Cr evaporation properties of selected FeCr alloys used as SOFCinterconnects // Int. J.
Hydrogen Energy. – 2013. – V. 38. – P. 15328-15334.296221. Tucker M.C., Kurokawa H., Jacobson C.P., De Jonghe L.C., Visco S.J. Afundamental study of chromium deposition on solid oxide fuel cell cathodematerials // J. Power Sources. – 2006. – V. 160.
– P. 130-138.222. Hou Y., Wu J., Konysheva E.Yu. Quantitative characterization of Cr–adsorptionon CeO2, pure and doped BaCeO3 and its impact on the electrochemicalperformance of Ce containing complex oxides // Int. J Hydrogen Energy. – 2016. –V. 41. – P. 3994-4004.223. Zhang X., Hou Y., Konysheva E.Yu. Quantitative correlation of Cr–depositionfrom the gas phase with chemical origin of electrolytes in SOFCs // Proceedings ofthe 12th European SOFC and SOE Forum.
Eds.: N. Brandon et al. Lucern.Switzerland. – 2016. – Р. 66-72.224. Jiang S.P., Zhang J.P., Zheng X.G. A comparative investigation of chromiumdeposition at air electrodes of solid oxide fuel cells // J. Eur. Ceram. Soc. – 2002. –V. 22. – P. 361-373.225. Zhen Y.D., Tok A.I.Y., Jiang S.P., Boey F.Y.C.
La(Ni,Fe)O3 as a cathodematerial with high tolerance to chromium poisoning for solid oxide fuel cells // J.Power Sources. – 2007. – V. 170. – P. 61-66.226. Paulson S.C., Birss V.I. Chromium poisoning of LSM–YSZ SOFC cathodes I.Detailed study of the distribution of chromium species at a porous, single–phasecathode // J Electrochem. Soc. – 2004. – V. 151. – P. A1961-A1968.227. Stodolny M.K., Boukamp B.A., Blank D.H.A., van Berkel F.P.F. La(Ni,Fe)O3stability in the presence of chromia – a solid–state reactivity study // J.Electrochem. Soc.
– 2011. – V. 158. – P. B112-В116.228. Stodolny M.K., Boukamp B.A., Blank D.H.A., van Berkel F.P.F. Impact of Cr–poisoning on the conductivity of LaNi0.6Fe0.4O3 // J. Power Sources. – 2011. – V.196. – P. 9290-9298.229. Stodolny M.K., Boukamp B.A., Blank D.H.A., van Berkel F.P.F. Cr–poisoningof a LaNi0.6Fe0.4O3 cathode under current load // J. Power Sources. – 2012. – V.209. – P. 120-129.297230. Huang B., Zhu X.J., Ren R.X., Hu Y.X., Ding X.Y., Liu Y.B., Liu Z.Y.Chromium poisoning and degradation at Gd0.2Ce0.8O2–impregnated LaNi0.6Fe0.4O3cathode for solid oxide fuel cell // J. Power Sources.
– 2012. – V. 216. – P. 89-98.231. Simner S., Stevenson J. Cathode–chromia interactions // Report on the 5th SECAannual workshop and the semi-annual core technology program peer review.Boston, USA. – 2004. – P. 30.232. Voorhoeve R.J.H., Remeika J.P., Freeland P.E., Matthias B.T. Rare–earth oxidesof manganese and cobalt rival platinum for the treatment of carbon monoxide inauto exhaust // Science. – 1972. – V. 177.
– P. 353-354.233. Lombardo E.A., Ulla M.A. Perovskite oxides in catalysis: past, present andfuture. // Res. Chem. Intermediat. – 1998. – V. 24. – P. 581-592.234. Sin A., Kopnin E., Dubitsky Y., Zaopo A., Aricò A.S., Gullo L.R., La Rosa D.,Antonucci V.J. Stabilisation of composite LSFCO–CGO based anodes for methaneoxidation in solid oxide fuel cells // J.
Power Sources. – 2005. – V. 145. – P. 68-73.235. Ferri D. NO reduction by H2 over perovskite–like mixed oxides // Appl. Catal.B. – 1998. – V. 16. – P. 339-345.236. Falcon H., Carbonio R.E., Fierro J.L.G. Correlation of oxidation states inLaFexNi1–xO3+ oxides with catalytic activity for H2O2 decomposition // J. Catal. –2001. – V. 203. – P. 264-272.237.
Petunchi J.O., Nicastro J.L., Lombardo E.A.J. Ethylene hydrogenation overLaCoO3 perovskite // Chem. Commun. – 1980. – V. 1980. – P. 467-468.238. Nakamura T., Petzow G., Gauckler L.J. Stability of the perovskite phase LaBО3(B = V, Cr, Mn, Fe, Co, Ni) in reducing atmosphere I. Experimental results // Mat.Res. Bul. – 1979. – V. 14.
– P. 649-659.239. Yokokawa H. Understanding materials сompatibility // Annu. Rev. Mater. Res.– 2003. – V. 33. – P. 581-610.240. Radovic M., Speakman S.A., Allard L.F., Payzant E.A., Lara–Curzio E., KrivenW.M., Lloyd J., Fegely L., Orlovskaya N. Thermal, mechanical and phase stabilityof LaCoO3 in reducing and oxidizing environments // J. Power Sources. – 2008.
–V. 184. – P. 77-83.298241. Misono M., Nitadori T. Redox and catalytic properties of perovskite–type mixedoxides. A comparative study of Ln1–xSrxBO3 (Ln=Rare earth, B=Co, Fe, Mn) //Stud. Surf. Sci. Catal. – 1985. – V. 21. – P. 409-419.242. Dai X., Yu C., Wu Q. Comparison of LaFeO3, La0.8Sr0.2FeO3, andLa0.8Sr0.2Fe0.9Co0.1O3 perovskite oxides as oxygen carrier for partial oxidation ofmethane // J. Nat.
Gas Chem. – 2008. – V. 17. – P. 415-418.243. Price P.M., Butt D.P. Stability and decomposition of Ca–substituted lanthanumferrite in reducing atmospheres // J. Am. Ceram. Soc. – 2015. – V. 98. – P. 28812886.244. Wei H.J., Cao Y., Ji W.J., Au C.T. Lattice oxygen of La1–xSrxMO3 (M = Mn, Ni)and LaMnO3–F perovskite oxides for the partial oxidation of methane tosynthesis gas // Catal.
Commun. – 2008. – V. 9. – P. 2509-2514.245. Valderrama G., Kiennemann A., Goldwasser M.R. Dry reforming of CH4 oversolid solutions of LaNi1–xCoxO3// Catal. Today. – 2008. – V. 133–135. – P. 142148.246. Sierra Gallego G., Mondragon F., Tatibouet J.M., Barrault J., Batiot–DupeyratC.
Carbon dioxide reforming of methane over La2NiO4 as catalyst precursor–characterization of carbon deposition. // Catal. Today. – 2008. – V. 133–135. – P.200-209.247. Sutthiumporn K., Maneerung T., Kathiraser Y., Kawi S. CO2 dry–reforming ofmethane over La0.8Sr0.2Ni0.8M0.2O3 perovskite (M = Bi, Co, Cr, Cu, Fe): roles oflattice oxygen on C–H activation and carbon suppression // Int. J HydrogenEnergy. – 2012. – V. 37. – P. 11195-11207.248.
