LaFe1–xNixO3−δ Preparation via Molten Salt Synthesis and Application in Limiting Current Oxygen Sensors

IF 3.4 2区化学 Q2 CHEMISTRY, MULTIDISCIPLINARY

Crystal Growth & Design Pub Date : 2025-09-01 DOI:10.1021/acs.cgd.5c01022

Junbo Long, Liang Wang, Jinlian Li, Xiaofang Zhang*, Jiegang You*, Qiying Zhang, Jiankang Wu, Junjie Shi and Xiaoshuang Guo,

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引用次数: 0

Abstract

LaFe_1–xNi_xO_3−δ (x = 0–0.5) mixed conductor materials were synthesized using molten salt synthesis with NaCl–KCl composite molten salt. The crystal structure, microstructure, reaction mechanism, and electronic conductivity were systematically investigated. XRD analysis confirms the formation of an orthorhombic perovskite phase. SEM revealed that the grains exhibit a regular tetragonal morphology. Electronic conductivity analysis reveals that the electronic conductivities of all samples meet the linear relationship with 1000/T at 650–830 °C. The composition with a Ni element doping concentration of x = 0.3 exhibits higher electronic conductivity. The limiting current oxygen sensor was fabricated using LaFe_0.7Ni_0.3O_3−δ as a dense diffusion barrier and 8 mol % yttria-stabilized zirconia (8YSZ) as the solid electrolyte assembled by the Pt sintered-paste method. The sensor exhibited stable operation at 760–850 °C and provided a 1–14 mol % oxygen measuring range. The oxygen sensor demonstrated excellent stability in limiting current and response time during 120 h of continuous operation at 850 °C.

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熔盐法制备LaFe1-xNixO3−δ及其在极限电流氧传感器中的应用

采用NaCl-KCl复合熔盐法合成了LaFe1-xNixO3−δ (x = 0-0.5)混合导体材料。对其晶体结构、微观结构、反应机理和电导率进行了系统的研究。XRD分析证实了正交钙钛矿相的形成。扫描电镜显示晶粒呈规则的四方形貌。电子电导率分析表明，在650 ~ 830℃时，所有样品的电子电导率与1000/T均满足线性关系。当Ni元素掺杂浓度为x = 0.3时，其电子导电性较高。以LaFe0.7Ni0.3O3−δ为致密扩散势垒，8mol %钇稳定氧化锆（8YSZ）为固体电解质，采用Pt烧结-糊法制备了极限电流氧传感器。该传感器在760-850°C范围内工作稳定，氧气测量范围为1-14 mol %。氧传感器在850°C下连续工作120小时，在限制电流和响应时间方面表现出优异的稳定性。

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来源期刊

Crystal Growth & Design 化学-材料科学：综合

CiteScore

6.30

自引率

10.50%

发文量

650

审稿时长

1.9 months

期刊介绍： The aim of Crystal Growth & Design is to stimulate crossfertilization of knowledge among scientists and engineers working in the fields of crystal growth, crystal engineering, and the industrial application of crystalline materials. Crystal Growth & Design publishes theoretical and experimental studies of the physical, chemical, and biological phenomena and processes related to the design, growth, and application of crystalline materials. Synergistic approaches originating from different disciplines and technologies and integrating the fields of crystal growth, crystal engineering, intermolecular interactions, and industrial application are encouraged.