A niobium and tantalum co-doped perovskite electrolyte with high ionic conduction for low-temperature Ceramics Fuel cell

IF 9 1区工程技术 Q1 ENERGY & FUELS

Renewable Energy Pub Date : 2024-09-24 DOI:10.1016/j.renene.2024.121466

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Abstract

In recent studies, fast ionic conduction through surface doping and coating has been a favorite subject and has indicated a promising and stable strategy to optimize ions in the developed electrolytes for low-temperature ceramic fuel cells (LT-CFCs). We have designed co-doped perovskite (Nb/Ta-SrCoO₃) to enhance further ionic properties using the Solid-state blending technique. The prepared SCNT (SrCoNb_0.3Ta_0.3O₃) was used as an electrolyte sandwiched between symmetrical electrodes and delivered attractive fuel cell performance (650 mW/cm²) with better stability at the low operating temperature of 520 °C compared to other compositions of SCNT. The low grain boundary resistance manifests SCNT's high ionic conduction + microstructural properties, assisting with higher fuel cell performance. The co-doping enables the fermi-level to move towards the -ive side, establishing a space charge region constituting BIEF (built in electric field) and helping to enhance the ions' transportation through the surface and interface. This work thus points out a new type of electrolyte with a different working mechanism from previous studies. It indicates a feasible approach to developing high-performing and stable electrolytes for LT-CFCs.

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用于低温陶瓷燃料电池的高离子传导性铌钽共掺杂过氧化物电解质

在最近的研究中，通过表面掺杂和涂层实现快速离子传导一直是一个热门话题，这也为优化低温陶瓷燃料电池（LT-CFCs）所开发电解质中的离子提供了一种前景广阔的稳定策略。我们设计了共掺杂包晶（Nb/Ta-SrCoO3），利用固态混合技术进一步增强离子特性。制备出的 SCNT（SrCoNb0.3Ta0.3O3）被用作夹在对称电极之间的电解质，与其他成分的 SCNT 相比，它在 520 °C 的低工作温度下具有更好的稳定性，燃料电池性能（650 mW/cm2）也很有吸引力。低晶界电阻体现了 SCNT 的高离子传导和微结构特性，有助于提高燃料电池性能。共掺杂使费米级向负电侧移动，建立了一个构成 BIEF（内置电场）的空间电荷区，有助于增强离子通过表面和界面的传输。因此，这项研究指出了一种新型电解质，其工作机制不同于以往的研究。它为开发高性能、稳定的 LT-CFC 电解质提供了一种可行的方法。

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来源期刊

Renewable Energy 工程技术-能源与燃料

CiteScore

18.40

自引率

9.20%

发文量

1955

审稿时长

6.6 months

期刊介绍： Renewable Energy journal is dedicated to advancing knowledge and disseminating insights on various topics and technologies within renewable energy systems and components. Our mission is to support researchers, engineers, economists, manufacturers, NGOs, associations, and societies in staying updated on new developments in their respective fields and applying alternative energy solutions to current practices. As an international, multidisciplinary journal in renewable energy engineering and research, we strive to be a premier peer-reviewed platform and a trusted source of original research and reviews in the field of renewable energy. Join us in our endeavor to drive innovation and progress in sustainable energy solutions.