通过电沉积制备用于质子交换膜水电解的自支撑催化剂:强调多孔传输层

EcoEnergy Pub Date : 2024-08-02 DOI:10.1002/ece2.55
Jin Uk Jang, Ashish Gaur, Sungwook Mhin, HyukSu Han
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引用次数: 0

摘要

质子交换膜水电解法(PEMWE)在解决全球环境和能源问题方面潜力巨大,因为气候变化和能源短缺带来的风险日益增加。然而,与替代能源相比,制氢的单位成本较低,在酸性环境中具有挑战性的操作条件阻碍了制氢的经济竞争力。因此,全球众多研究人员一直致力于提高 PEMWE 系统中重要组件的效率,特别是多孔传输层 (PTL)。此外,催化剂层(CL)和多孔传输层(PTL)之间的界面与系统性能直接相关,因此研究催化剂层和多孔传输层之间的界面对于未来的可持续发展和降低成本至关重要。本综述重点分析了提高 PTL 性能的制造技术、材料和结构配置。此外,我们还建议使用自支撑催化剂作为潜在的解决方案,以增强 CL 与 PTL 之间界面的质量和电荷转移,从而促进氢气的大规模生产。在最后一部分,我们将概述下一代 PEMWE 在高效制氢方面的未来发展轨迹和潜力。
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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Fabrication of self-supported catalysts via electrodeposition for proton exchange membrane water electrolysis: Emphasizing on the porous transport layers

The potential of proton exchange membrane water electrolysis (PEMWE) is enormous in tackling worldwide environmental and energy issues in the face of increasing risks associated with climate change and energy scarcity. Nevertheless, the economic competitiveness of hydrogen production is hindered by the challenging operating conditions in acidic environments, resulting in a lower unit cost compared to alternative energy sources. Hence, numerous global research endeavors persist in enhancing the efficiency of essential components in PEMWE systems, specifically the porous transport layer (PTL). Additionally, investigating the interface between catalyst layer (CL) and PTL, which is directly associated with system performance, is imperative for future sustainability and cost reduction. This review focuses on the analysis of fabrication techniques, materials, and structural configurations to enhance the performance of PTLs. Additionally, we suggest the use of self-supported catalysts as potential solutions to enhance mass and charge transfer at the interface between CLs and PTLs, hence facilitating the production of hydrogen on a wide scale. In the last section we provide an overview of the future trajectory and potential of next-generation PEMWE in the context of efficient hydrogen production.

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