为先进燃料电池量身定制离子电子混合导体的新兴半导体离子材料

Bushra Bibi , Atif Nazar , Bin Zhu , Fan Yang , Muhammad Yousaf , Rizwan Raza , M.A.K. Yousaf Shah , Jung-Sik Kim , Muhammad Afzal , Yongpeng Lei , Yifu Jing , Peter Lund , Sining Yun
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摘要

混合离子电子导体(MIECs)在能源转换和储存技术领域发挥着至关重要的作用,其重点是电极材料在固体氧化物燃料电池(SOFCs)和质子传导陶瓷燃料电池(PCFCs)中的应用。与此同时,半导体离子材料(SIMs)的出现为功能材料领域引入了新的范式,特别是用于低温(300-550 °C)SOFC 和 PCFC 的电极和电解质开发。这篇综述文章批判性地探讨了 MIEC 和 SIMs 之间协同作用的复杂机制,尤其侧重于阐明半导体离子膜燃料电池(SIMFC)的基本工作原理。通过探索离子耦合电子转移/传输、结点效应、能带排列和理论计算等关键方面,该研究揭示了 MIECs 的变革潜力,还涉及 SIMs 和先进燃料电池(FCs)背景下的三电荷导电氧化物(TCOs)。本文所阐述的见解和发现,通过将 MIEC(三电荷导电氧化物)量身定做为实现高性能 SIMFC 的可行途径,极大地推动了 SIMs 和 SIMFC 的发展。这一科学探索不仅解决了围绕高效电荷转移、离子传输和功率输出的持续挑战,还为 FC 技术的广泛商业化释放了巨大潜力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Emerging semiconductor ionic materials tailored by mixed ionic-electronic conductors for advanced fuel cells
Mixed ionic-electronic conductors (MIECs) play a crucial role in the landscape of energy conversion and storage technologies, with a pronounced focus on electrode materials’ application in solid oxide fuel cells (SOFCs) and proton-conducting ceramic fuel cells (PCFCs). In parallel, the emergence of semiconductor ionic materials (SIMs) has introduced a new paradigm in the field of functional materials, particularly for both electrode and electrolyte development for low-temperature, 300–550 ​°C, SOFCs, and PCFCs. This review article critically delves into the intricate mechanisms underpinning the synergistic relationship between MIECs and SIMs, with a particular emphasis on elucidating the fundamental working principles of semiconductor ionic membrane fuel cells (SIMFCs). By exploring critical facets such as ion-coupled electron transfer/transport, junction effect, energy bands alignment, and theoretical computations, it casts an illuminating spotlight on the transformative potential of MIECs, also involving triple charge conducting oxides (TCOs) in the context of SIMs and advanced fuel cells (FCs). The insights and findings articulated herein contribute substantially to the advancement of SIMs and SIMFCs by tailoring MIECs (TCOs) as promising avenues toward the emergence of high-performance SIMFCs. This scientific quest not only addresses the insistent challenges surrounding efficient charge transfer, ionic transport and power output but also unlocks the profound potential for the widespread commercialization of FC technology.
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