Диссертация (Перовскитоподобные материалы на основе переходных и редкоземельных металлов закономерности химической и термической стабильности), страница 48

– 1997. – V. 101–103. – P.661-666.160. Wang W., Zhang H.B., Lin G.D., Xiong Z.T. Study of Ag/La0.6Sr0.4MnO3catalysts for complete oxidation of methanol and ethanol at low concentrations //Appl. Catal. B. – 2000. – V. 24. – P. 219-232.161. Caillol N., Pijolat M., Siebert E. Investigation of chemisorbed oxygen, surfacesegregation and effect of post–treatments on La0.8Sr0.2MnO3 powder and screen–printed layers for solid oxide fuel cell cathodes // Appl. Surf.

Sci. – 2007. – V. 253.– P. 4641-4648.162. la O’ G.J., Savinell R.F., Shao–Horn Y. Activity enhancement of densestrontium–doped lanthanum manganite thin films under cathodic polarization: acombined AES and XPS Study // J. Electrochem. Soc. – 2009. – V. 156. – P.B771-B781.163. Mitterdorfer A., Gauckler L.J. La2Zr2O7 formation and oxygen reductionkinetics of the La0.85Sr0.15MnyO3, O2(g)|YSZ system // Solid State Ionics. – 1998. –V. 111.

– P. 185-218.164. Chen M., Liu Y.L., Hagen A., Hendriksen P.V., Poulsen F.W. LSM–YSZReactions in different atmospheres // Fuel cells. – 2009. – V. 9. – P. 833-840.290165. Tu H.Y., Takeda Y., Imanishi N., Yamamoto O. Ln0.4Sr0.6Co0.8Fe0.2O3–δ (Ln=La,Pr, Nd, Sm, Gd) for the electrode in solid oxide fuel cells // Solid State Ionics. –1999. – V. 117. – P. 277-281.166. Kim W.H., Song H.S., Moon J., Lee H.W. Intermediate temperature solid oxidefuel cell using (La,Sr)(Co,Fe)O3–based cathodes // Solid State Ionics. – 2006. – V.177. – P.

3211-3216.167. Shiono M., Kobayashi K., Nguyen T.L., Hosoda K., Kato T., Ota K., Dokiya M.Effect of CeO2 interlayer on ZrO2 electrolyte/La(Sr)CoO3 cathode for low–temperature SOFCs // Solid State Ionics. – 2004. – V. 170. – P. 1-7.168 Chiba R., Orui H., Komatsu T., Tabata Y., Nozawa K., Arakawa M., Sato K.,Arai H. LaNi0.6Fe0.4O3–сeria composite cathode for SOFCs operating atintermediate temperatures // J. Electrochem. Soc. – 2008. – V. 155. – P. B575B580.169. Kostogloudis G.Ch., Tsiniarakis G., Ftikos Ch.

Chemical reactivity of perovskiteoxide SOFC cathodes and yttria stabilized zirconia // Solid State Ionics. – 2000. –V. 135. – P. 529-535.170. Hanse K.K., Hansen K.V. A–site deficient (La0.6Sr0.4)1−sFe0.8Co0.2O3−δperovskites as SOFC cathodes // Solid State Ionics. – 2007. – V. 178. – P. 13791384.171. Qiang F., Sun K.N., Zhang N.Q., Zhu X.D., Le S.R., Zhou D.R.Characterization of electrical properties of GDC doped A–site deficient LSCFbased composite cathode using impedance spectroscopy // J.

Power Sources. –2007. – V. 168. – P. 338-345.172. Penwell W.D., Giorgi J.B. Conductivity of cerium doped BaFeO3– andapplications for the detection of oxygen // Sensors and Actuators B: Chemical. –2014. – V. 191. – P. 171-177.173. Hashimoto S., Iwahara H. Structural, thermal and electrical properties of Ce–doped SrMnO3 // J.

Electroceramics. – 2000. – V. 4. – P. 225-231.291174. Jeong C., Ryu J., Noh T., Kim Y.N., Lee H. Structural analysis and electrodeperformance of Ce doped SrMnO3 synthesized by EDTA citrate complexingprocess // Adv. Appl. Ceram. – 2013. – V. 112. – P. 494-498.175. Kuritsyna I.E., Sinitsyn V.V., Fedotov Yu.S. , Bredikhin S.I. , Tsipis E.V.,Kharton V.V. Stability and functional properties of Sr0.7Ce0.3MnO3–δ as cathodematerial for solid oxide fuel cells // Rus.

J. Electrochem. – 2014. – V. 50. – P. 713718.176. Ryu J., O’Hayre R., Lee H. Structural analysis and electrochemical properties ofcobalt–doped Sr0.9Ce0.1MnO3– cathode for IT–SOFCs // J. Mater. Res. – 2014. –V. 29. – P. 2667-2672.177. Adler S.B. Factors governing oxygen reduction in solid oxide fuel cell cathodes.// Chem. Rev. – 2004. – V.

104. – P. 4791-4843.178. Juhl M., Primdahl S., Manon C., Mogensen M. Performance/structurecorrelation for composite SOFC cathodes // J. Power Sources. – 1996. – V. 61. – P.173-181.179. Murray E.P., Tsai T., Barnett S.A. Oxygen transfer processes in (La,Sr)MnO3/Y2O3–stabilized ZrO2 cathodes: an impedance spectroscopy study // Solid StateIonics. – 1998. – V. 110. – P. 235-243.180. Wei F., Cao H.L., Chen X. La0.6Sr0.4CoO3––Ce0.8Gd0.2O2– nanocompositesprepared by a sol–gel process for intermediate temperature solid oxide fuel cellcathode applications // J. Mater.

Sci. – 2016. – V. 51. – P. 2160-2167.181. Kenjo T., Nishiya M. LaMnO3 air cathodes containing ZrO2 electrolyte for hightemperature solid oxide fuel cells // Solid State Ionics. – 1992. – V. 57. – P. 295302.182. Murray E.P., Barnett S.A. (La,Sr)MnO3–(Ce,Gd)O2–x composite cathodes forsolid oxide fuel cells // Solid State Ionics. – 2001.

– V. 143. – P. 265-273.183. Mamak M., Metraux G.S., Petrov S., Coombs N., Ozin M.A., Green G.A.Lanthanum strontium manganite/yttria–stabilized zirconia nanocomposites derivedfrom a surfactant assisted, co–assembled mesoporous phase // J. Am. Chem. Soc.2003. – V. 125. – P. 5161-5175.292184. Nie H., Wang S., Wang Z., Qian J., Wen T.L. Optimization of La 0.6Sr0.4CoO3–Ce0.8Gd0.2O1.9 composite cathodes for ITSOFCs // Solid State Ionics. – 2011. – V.192. – P.

483-485.185. Lou X.Y., Liu Z., Wang S., Xiu Y.H., Wong C.P., Liu M., Controlling themorphology and uniformity of a catalyst–infiltrated cathode for solid oxide fuelcells by tuning wetting property// J. Power Sources. – 2010. – V. 195. – P. 419424.186. Knöfel C., Chen M., Mogensen M. The effect of humidity and oxygen partialpressure on LSM–YSZ cathode // Fuel cells. – 2011.

– V. 11. – P. 669–677.187. Liu Y.H., Wang F.Z., Chi B., Pu J., Jian L., Jiang S.P. A stability study ofimpregnated LSCF–GDC composite cathodes of solid oxide fuel cells // J. AlloyCompd. – 2013. – V. 578. – P. 37-43.188. Liu Y.H., Cao Y., Yang S.B., Yan D., Chi B., Pu J., Jian L. Effects of oxygenpartial pressure on the performance stability of impregnated La0.6Sr0.4Co0.2Fe0.8O3–Sm0.2Ce0.8O2 cathodes of solid oxide fuel cells // Fuel Processing Technology. –2015. – V.

135. – P. 203-206.189. Skinner S.J., Kilner J.A. Oxygen diffusion and surface exchange inLa2–xSrxNiO4+ // Solid State Ionics. – 2000. – V. 135. – P. 709-712.190. Al Daroukh M., Vashook V.V., Ullmann H., Tietz F., Raj I.A. Oxides of theAMO3 and A2MO4–type: structural stability, electrical conductivity and thermalexpansion // Solid State Ionics. – 2003. – V. 158. – P.

141-150.191. Munnings C.N., Skinner S.J., Amow G., Whitfield P.S., Davidson I.J. Oxygentransport in the La2Ni1–xCoxO4+ system // Solid State Ionics. – 2005. – V. 176. – P.1895-1901.192. Mauvy F., Lalanne C., Bassat J.M., Grenier J.C., Zhao H., Huo L., Stevens P.J.Electrode properties of Ln2NiO4+δ (Ln=La, Nd, Pr): AC impedance and DCpolarization studies // Electrochem. Soc. – 2006. – V. 153. – P. A1547-A1553.193. Kaluzhskikh M.S., Kazakova S.M., Mazo G.N., Istomin S.Ya., Antipov E.V.,Gippius A.A., Fedotov Yu., Bredikhin S.I., Liu Y., Svensson G., Shen Z.

High–temperature crystal structure and transport properties of the layered cuprates293Ln2CuO4, Ln=Pr, Nd and Sm // J. Solid State Chem. – 2011. – V. 184. – P. 698704.194. Zhao H., Li Q., Sun L.P. Ln2MO4 cathode materials for solid oxide fuel cells //Science China Chemistry. – 2011. – V. 54. – P. 898-910.195. Philippeau B., Mauvy F., Mazataud C., Fourcade S., Grenier J.C. Comparativestudy of electrochemical properties of mixed conducting Ln2NiO4+δ (Ln = La, Prand Nd) and La0.6Sr0.4Fe0.8Co0.2O3– as SOFC cathodes associated to Ce0.9Gd0.1O2–,La0.8Sr0.2Ga0.8Mg0.2O3– and La9Sr1Si6O26.5 electrolytes // Solid State Ionics. – 2013.– V.

249-250. – P. 17-25.196. Sadykov V.A., Eremeev N.F., Usol‘tsev V.V., Bobin A.S., Alikin G.M.,Pelipenko V.V., Sadovskay E.M., Muzykantov V.S., Bulgakov N.N., Uvarov N.F.Mechanism of oxygen transfer in layered lanthanide nickelates Ln2–xNiO4+δ (Ln =La, Pr) and their nanocomposites with Ce0.9Gd0.1O2–δ and Y2(Ti0.8Zr0.2)1.6Mn 0.4O7–δsolid electrolytes // Rus. J. Electrochem.