Synthesis and Characterization of Sc and Y Co-doped Zirconia (Zr0.84Y0.08Sc0.08O1.92) Electrolyte Prepared by Sol-Gel Method

M. Villanueva, R. Garcia, R. Cervera
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引用次数: 5

Abstract

Y and Sc co-doped ZrO2 [Zr0.84Y0.08Sc0.08O1.92 (4Sc4YSZ)] solid electrolyte was prepared via an alkoxide sol-gel route. 4Sc4YSZ was characterized by TG-DTA, XRD, SEM-EDS and AC impedance spectroscopy. XRD patterns showed that co-doping with Y and Sc resulted to the successful stabilization of the highly conductive cubic phase with a lattice parameter of 5.12 Å. Y and Sc dopants are well-distributed within the ZrO2 particles as evidenced by EDS elemental maps. Total conductivities from 500 °C to 700 °C were determined from AC impedance spectroscopy and an activation energy of 1.31 eV (500-650 °C) was calculated. Even at a low sintering condition of 1200 °C for 5 h, a promising conductivity of 109 mS/cm was achieved for 4Sc4YSZ at 700 °C which is higher than the conductivity of typical 8YSZ solid electrolyte.
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溶胶-凝胶法制备Sc、Y共掺杂氧化锆(Zr0.84Y0.08Sc0.08O1.92)电解质及其表征
采用醇盐溶胶-凝胶法制备了Y、Sc共掺杂ZrO2 [Zr0.84Y0.08Sc0.08O1.92 (4Sc4YSZ)]固体电解质。采用TG-DTA、XRD、SEM-EDS和交流阻抗谱对4Sc4YSZ进行了表征。XRD谱图表明,Y和Sc共掺杂可成功稳定高导电性立方相,其晶格参数为5.12 Å。EDS元素图表明,Y和Sc掺杂剂均匀分布在ZrO2颗粒内。通过交流阻抗谱测定了500 ~ 700°C的总电导率,计算出500 ~ 650°C的活化能为1.31 eV。即使在1200°C低烧结5 h的条件下,4Sc4YSZ在700°C时的电导率也达到了109 mS/cm,高于典型的8YSZ固体电解质的电导率。
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