Li_(2)CO_(3)对BaZr_(0.1)Ce_(0.7)Y_(0.1)Yb_(0.1)O_(3-δ)质子导体电解质性能的影响

开发及制备高性能电解质材料有助于质子导体固体氧化物燃料电池(Protonic Ceramic Fuel Cell,PCFC)迈向商业化。BaZr_(0.1)Ce_(0.7)Y_(0.1)Yb_(0.1)O_(3-δ)(BZCYYb)是一种十分具有应用前景的PCFC电解质材料,在中低温下(400℃~700℃)具有足够的化学稳定性和优异的离子导电性。然而,BZCYYb烧结活性低的问题阻碍了其在PCFC中的应用。通过改进的Pechini法合成BZCYYb粉体,以无机盐Li_(2)CO_(3)作为烧结助剂,采用机械球磨混合的工艺将其引入BZCYYb粉体制备出PCFC电解质。实验结果表明,添加Li_(2)CO_(3)可以明显提高电解质致密化程度,且不改变BZCYYb的晶型及物相。对于添加8 mol%Li_(2)CO_(3)的BZCYYb试样,在1350℃保温3 h后,其相对致密度及线性收缩率分别为95.37%和17.90%,其在700℃时的电导率为1.922×10^(-2)S·cm^(-1),而在1450℃下保温5 h后,未添加Li_(2)CO_(3)的BZCYYb试样的电导率为1.493×10^(-2)S·cm^(-1),表明添加适量的Li_(2)CO_(3)可显著降低BZCYYb的烧结温度,且材料的电导率略有增加。

Silver particle interlayer with high dislocation density for improving the joining of BaZr_(0.1)Ce_(0.7)Y_(0.1)Yb_(0.1)O_(3-δ) electrolyte and AISI 441 interconnect

One of the critical challenges for the protonic ceramic fuel cell stack is sealing electrolytes and interconnects.However,the traditional AgeCuO sealant will aggravate the oxidation along the interconnect surface and result in brittle compound layers at the BaZr_(0.1)Ce_(0.7)Y_(0.1)Yb_(0.1)O_(3-δ)(BZCYYb)electrolyte interface.The present work demonstrates that a silver particle interlayer with high dislocation density can be adopted to join BZCYYb electrolyte to the interconnect(AISI 441 stainless)in air instead of traditional AgeCuO sealant.Elevating temperatures result in a sufficient bonding at the Ag/BZCYYb interface,and a defect-free joint is obtained at 950℃.Atomic bonding at Ag/BZCYYb interface is confirmed by TEM.Also,a dense and thin oxide layer(2-3 μm)is formed along the AISI 441 interface.Ag particles in the interlayer provide the main driving force for the sintering joining.The massive dislocations promote the recovery and recrystallization of the Ag interlayer,as well as the interdiffusion of BZCYYb/Ag.After aging in the wet oxidizing atmosphere at 600℃ for 300 h,joints remain intact and dense,indicating superior oxidation resistance and aging performance.Besides,the joint shear strength(25.3 MPa)is 59%higher than that of the joint brazed by traditional AgeCuO.

铈、钇双掺杂钙钛矿型复合氧化物的合成及其在常压合成氨中的应用

采用溶胶 凝胶法合成了BaZr0.9Y0.1O3-δ(BZY),BaCe0.2Zr0.7Y0.1O3-δ(BCZY)固体电解质前驱体,并在1300℃烧结成致密陶瓷。采用热重差热分析(TG DTA),X射线衍射分析(XRD)及电镜测试(SEM,TEM)对样品进行了表征。并以烧结体样品为固体电解质、银钯作电极,测定了其在不同气氛和温度下的电导率。将该陶瓷用于固态质子传导电池中,在常压下以氮气和氢气为原料合成了氨气。结果表明,氨的比产率可达2.93×10-9mol·s-1·cm-2。

熔盐法制备BZCY质子导体电解质材料

为了解决BaZr_(0.1)Ce_(0.7)Y_(0.2)O_(3-δ)(BZCY)质子导体电解质材料制备温度高和耗能大的问题,采用熔盐法制备BZCY钙钛矿材料。使用摩尔比为1∶1的NaCl和KCl作为熔盐介质,通过调控氯盐与金属硝酸盐的投料比来调控材料的形貌,氯盐与金属硝酸盐的投料比为2∶1时,BZCY粉体颗粒的分散性较好,且具有较高的质子电导率,在600℃达到5.99×10^(-2) S·cm^(-1)。采用干压、共烧和喷涂技术制备了以BZCY为电解质的纽扣电池,单电池展示出优异的电化学性能,650℃时,最大功率密度达到668 mW·cm^(-2),开路电压达到1.03 V。