湿粉末喷涂法研究质子陶瓷薄膜电解质的结构均匀性和完整性

IF 5.4 Q2 CHEMISTRY, PHYSICAL
Wuxiang Feng , Wei Wu , Congrui Jin , Meng Zhou , Wenjuan Bian , Wei Tang , Joshua Y. Gomez , Richard Boardman , Dong Ding
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引用次数: 8

摘要

薄的质子陶瓷电解质有助于降低质子陶瓷电化学电池的欧姆电阻,提高其电化学性能。然而,大规模薄电解质的制造仍然是一个挑战。当先进的雾化技术和优化的喷涂工艺相结合时,湿式粉末喷涂是一种极具吸引力的沉积10 μm薄电解质的技术。在这里,超声波雾化与湿粉喷涂技术相结合,以减少电解质的厚度。此外,还对湿式粉末喷涂工艺进行了参数化研究,以获得均匀无裂纹的电解质膜。结果表明,调整固体加载率和喷涂道数可以影响喷涂电解质膜的形貌,使烧结电解质层结构致密。为了在烧结过程中保持电解质层的化学稳定性,进一步研究了烧结温度的影响,以制备物理薄、结构致密、化学均匀的电解质层。采用优化的喷涂和烧结工艺制备的质子陶瓷电化学电池在燃料电池和电解模式下均表现出优异的性能。此外,在氧化还原和长期稳定性测试中,细胞表现出显著的结构完整性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Exploring the structural uniformity and integrity of protonic ceramic thin film electrolyte using wet powder spraying

Thin protonic ceramic electrolyte contributes to lower ohmic resistance and enhances electrochemical performance of protonic ceramic electrochemical cells. However, manufacturing of large-scale thin electrolyte remains a challenge. Wet powder spraying is an attractive technique to deposit <10 μm thin electrolyte when advanced atomizing techniques and optimized spraying process are integrated. Here ultrasonic atomization is integrated in the wet powder spray technique to reduce the thickness of electrolyte. Moreover, a parametric study is conducted to optimize the wet powder spray process to deposit uniform and crack-free electrolyte film. It is illustrated that tuning of solid loading rates and spray passes can affect the morphology of the as-sprayed electrolyte film, enabling the structural compactness of the sintered electrolyte layer. To maintain chemical stability of the electrolyte layer during sintering, effect of sintering temperature is further investigated to produce a physically thin, structurally dense, and chemically homogeneous electrolyte layer. The protonic ceramic electrochemical cells fabricated with optimized spraying and sintering parameters demonstrate excellent performance under both fuel cell and electrolysis modes. In addition, the cells exhibit remarkable structural integrity during redox and long-term stability tests.

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来源期刊
CiteScore
9.10
自引率
0.00%
发文量
18
审稿时长
64 days
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