中温直接碳氢化合物固体氧化物燃料电池Cu-CeO_2-ScSZ阳极的研究

采用共沉淀法合成了氧化钪稳定氧化锆(9 mol%Sc_2O_3,ScSZ)粉末。应用热膨胀分析仪研究了ScSZ粉末的烧结特性,采用扫描电镜观察了烧结试样的微观组织,利用交流阻抗法测定了ScSZ电解质在500～900℃的电导率。制备了以ScSZ为电解质、Cu-CeO_2-ScSZ为阳极、ScSZ-LSM为阴极的阳极支撑燃料电池。在700℃时,直接以氢气、丁烷和甲烷为燃料,测得的电池最大输出功率密度分别为280 mW/cm^2、142 mW/cm^2和120 mW/cm^2。

Al_2O_3或TiO_2掺杂的ScSZ固体电解质纳米晶薄膜的制备及表征

利用溶胶 凝胶旋涂法 ,在单晶硅基片 (10 0 )上分别制得了厚度约为 0 31μm的(Al2 O3) 0 .10 (Sc2 O3) 0 .0 8(ZrO2 ) 0 .82 和 0 36 μm的 (Sc2 O3) 0 .12 5(TiO2 ) 0 .175(ZrO2 ) 0 .70 固体电解质纳米晶薄膜。烧结实验结果表明 ,两种薄膜均在 6 50℃以上开始晶化 ,温度越高 ,晶化越完全 ,在 80 0℃可完全晶化 ;所得纳米晶颗粒呈纯的萤石结构立方相 ;铝和钛掺杂的纳米晶颗粒的平均大小分别为4 7和 51nm。铝掺杂的薄膜非常均匀致密 ,然而 。

纳米ScSZ基电解质中低温导电性研究进展

固体氧化物燃料电池(SOFC)适用于多种燃料气体,高效清洁,是最有前景的燃料电池之一。氧化钪(Sc2O3)掺杂二氧化锆(ZrO2)系列(ScSZ)使氧化锆基电解质表现出优异的离子导电性。ScSZ基电解质晶粒纳米化呈现出了很好的电学性能而得到广泛深入的研究。但是ScSZ基电解质在中低温下会发生相变,产生低导电性的菱形相而影响其离子电导率。系统总结了单元或二元氧化物掺杂ScSZ电解质在中低温下的物相、晶体结构及电导率。多元氧化物复合掺杂ScSZ可有效防止在中低温下发生相变、稳定立方相ScSZ。采用不同方法制备纳米ScSZ基电解质,可很好地提高电解质的电导率。提出了ScSZ系列在中低温范围内(600~800℃)的发展方向:优化掺杂成分和掺杂量提高晶粒晶界电导率,使用不同工艺制备纳米电解质或不同制备方法制备新型结构电解质材料。

固体氧化物燃料电池用ScSZ粉体的研究进展

介绍了固体氧化物燃料电池(SOFC)的工作原理和特点,综述了钪稳定氧化锆(ScSZ)粉体的电解质机理、制备方法较全面地对ScSZ粉体的研究进展进行了论述。

固体氧化物燃料电池用ScSZ粉体的研究

介绍了固体氧化物燃料电池(SOFC)的工作原理和特点,综述了钪稳定氧化锆(ScSZ)粉体的电解质机理、制备方法和研究进展,对ScSZ粉体的发展进行了展望。

Sc_(2)O_(3)掺杂对ScSZ粉体制备过程的影响研究

本文以ZrOCl_(2)·8H2O和Sc_(2)O_(3)为原料,聚乙二醇(PEG800)为分散剂,氨水为沉淀剂,采用共沉淀法制备了不同钪掺杂量的氧化钪稳定氧化锆(ScSZ)复合粉体,并通过TG/DSC热分析、ICP、XRD、Raman和SEM等分析手段对样品进行表征,研究了Sc_(2)O_(3)掺杂对ZrO_(2)前驱体热稳定性和ZrO_(2)粉体物相、形貌等的影响,还探讨了洗涤方式对所制备的ScSZ粉体形貌的影响。结果表明:ZrO_(2)和ScSZ前驱体均为无定形状态,经煅烧后ScSZ前驱体的总失重量大于ZrO_(2)前驱体的总失重量;未掺杂钪所制备的ZrO_(2)粉体为单斜相,钪掺杂改变了物相,ScSZ粉体为四方和立方相的混合晶型;钪掺杂对ZrO_(2)粉体的粒径无明显影响,ZrO_(2)和ScSZ粉体均发生一定团聚,团聚体直径约为0.5~3μm;采用乙醇洗涤有利于减小ScSZ粉体的初级纳米颗粒粒径,减小团聚现象,粉末团聚较松散。

等离子放电烧结制备10ScSZ细晶块体及其烧结温度探究

采用燃烧法制备10ScSZ粉体,通过等离子放电烧结(SPS)制备10ScSZ细晶致密陶瓷块体。根据SPS上下电极间距随烧结温度的变化绘制烧结曲线,在1200℃附近电极间距最小,判断陶瓷致密化温度在1200℃左右。为验证该方法的可靠性,选取1050,1100,1150,1200,1250℃作为烧结温度分别制备样品。结果表明,在1150℃烧结的10ScSZ样品具有最高的致密度,达到99.4%,且具有平均晶粒尺寸为194 nm的细晶结构,与推测结果基本相符。该实验结果证实了在SPS烧结中通过烧结曲线判断合适的烧结温度是一种高效可行的方法。

甘氨酸-硝酸盐法制备(Y_2O_3)_(0.02)-(Sc_2O_3)_(0.11)-(ZrO_2)_(0.87)超细粉体

通过甘氨酸-硝酸盐法(GNP)制备了(Y2O3)0.02-(Sc2O3)0.11-(ZrO2)0.87(2Y-11ScSZ)超细粉体。研究了不同甘氨酸用量对粉体相结构和形貌的影响。然后采用流延成型方法制备薄膜样品,讨论不同烧结温度对样品的影响。实验结果表明:2%物质的量浓度Y2O3的添加能稳定11ScSZ在立方相结构。随着甘氨酸用量的增加,粉体粒径逐渐增大。确定了烧结样品在1300℃即可达到致密化。

Influence of characteristics of stabilized zirconia electrolyte on performance of cermet supported tubular SOFCs

Ni-Al2O3 cermet supported tubular SOFC was fabricated by thermal spraying. Flame-sprayed Al2O3-Ni cermet coating plays dual roles of a support tube and an anode current collector. 4.5mol.% yttria-stabilized zirconia (YSZ) and 10mol.% scandia-stabilized zirconia (ScSZ) coatings were deposited by atmospheric plasma spraying (APS) as the electrolyte in present study. The electrical conductivity of electrolyte was measured using DC method. The post treatment was employed using nitrate solution infiltration to densify APS electrolyte layer for improvement of gas permeability. The electrical conductivity of electrolyte and the performance of single cell were investigated to optimize SOFC performance. The electrical conductivity of the as-sprayed YSZ and ScSZ coating is about 0.03 and 0.07 S·cm-1 at 1000 ℃, respectively. The ohmic polarization significantly influences the performance of SOFC. The maximum output power density at 1000 ℃ increases from 0.47 to 0.76 W·cm-2 as the YSZ electrolyte thickness reduces from 100 μm to 40 μm. Using APS ScSZ coating of about 40 μm as the electrolyte, the test cell presents a maximum power output density of over 0.89 W·cm-2 at 1000 ℃.

Sc2O3稳定ZrO2电解质材料及其研究进展

固体氧化物燃料电池(SOFC)是高效洁净利用碳基燃料的有效途径,具有高效率、环境友好、全固态结构等特点,并且适用于多种燃料气体,因此成为能源和材料领域的热点之一。SOFC的国际发展趋势是中温化,具有投资小、材料成本较低、电极不易老化、界面反应可有效控制等优点。电解质是整个SOFC的核心部件,增强电解质的电导率,开发高性能的电解质材料是SOFC实现大规模发展的关键。目前SOFC所使用的电解质主要为锆基固体电解质,其中Sc_2O_3稳定ZrO_2(ScSZ)是锆基固体电解质中离子电导率最高的电解质材料,是中温SOFC(ITSOFC)首选电解质。首先介绍了固体氧化物燃料电池的结构、工作原理、对电解质的材料要求及其技术发展趋势,然后阐述了ScSZ电解质材料的晶体结构、离子导电机制。重点总结了ScSZ电解质材料研究现状、发展趋势及发展前景。

Preparation and electrical characterization of ultra-fine powder scandia-stabilized zirconia

Ultrafine powders of scandia-stabilized zirconia (ScSZ) were prepared by the co-precipitation method, using ZrOCl2 and ScO2 as raw materials and NH3·H2O as a precipitant. In this paper, the optimum process parameters were investigated. The pH of the reaction solution directly impacted the precursor structure, which further affected the obtained crystal forming. Many experiment methods of thermogravimetric analysis and differential thermal analysis (TG-DTA), X-ray diffraction (XRD), transmission electron microscopy (TEM), Raman spectroscopy (Raman), and nitrogen adsorption were employed to characterize the ScSZ powder. The structure transition mechanism from cubic to rhombohedral was discussed. In addition, the electrical conductivity of the powders was also studied after dry-pressing and calcining. The results showed that the structure of ScSZ with complete crystal surface belonged to the cubic phase. The crystallite sizes of the powders prepared are about 60–80 nm, meet the conditions of (D90–D10)/2D50≤1, and ex-hibited the good flow properties. The electrical conductivity was more than 190 mS/cm in air measured at 850 oC.