Unravelling the potential of prussian blue analogues in oxygen electrocatalysis: A perspective on surface reconstruction

IF 3.8 Q2 CHEMISTRY, PHYSICAL
Priya Jain, Pravin Popinand Ingole
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Abstract

Prussian blue analogues (PBAs) hold promises as catalysts for electrochemical energy conversion, especially in the oxygen reduction reaction (ORR) and the oxygen evolution reaction (OER). Their high surface area and porosity combined with a tunable electronic structure featuring abundant metallic centers, make them attractive alternatives to traditional noble metal-based catalysts. Amongst these fascinating properties, the capacity for surface reconstruction to form active layers is one of the most sought-after characteristics of PBAs for enhanced activity. Recent advancements in operando and in situ techniques have further highlighted PBAs' capability for surface reconstruction during the electrocatalysis, particularly in alkaline solutions. State-of-the-art strategies for enhancing activity and stability of PBA-based catalysts, such as metal doping, tuning metal centers, introducing coordination sphere vacancies (VFeCN), and utilizing carbon supports, are closely linked to their ability towards surface reconstruction. However, key aspects warrant further exploration to achieve high electrocatalytic activity, including identifying initiators and pathways for surface reconstruction, establishing structure-property-activity correlations, and strategically manipulating in-situ catalyst surface reconstruction. This perspective focuses on understanding the transformation of PBA-based pre-catalysts to surface active layers on catalysts via surface reconstruction. A recent progress in PBA-catalysts towards advancing the electrochemical energy systems is highlighted. This perspective will guide the new entrants in the field to understand the process of surface transformation for establishing structure-property-activity relationships and thus to develop highly efficient PBA-based electrocatalysts.

Abstract Image

揭示普鲁士蓝类似物在氧电催化中的潜力:表面重构的视角
普鲁士蓝类似物(PBAs)有望成为电化学能量转换的催化剂,特别是在氧还原反应(ORR)和氧进化反应(OER)中。它们的高比表面积和多孔性,加上具有丰富金属中心的可调电子结构,使它们成为传统贵金属催化剂的诱人替代品。在这些迷人的特性中,表面重构形成活性层的能力是 PBAs 在提高活性方面最受欢迎的特性之一。最近在操作和原位技术方面取得的进展进一步突出了 PBA 在电催化过程中的表面重构能力,尤其是在碱性溶液中。提高基于 PBA 催化剂的活性和稳定性的最先进策略,如金属掺杂、调整金属中心、引入配位球空位(VFeCN)和利用碳载体,都与它们的表面重构能力密切相关。然而,要实现高电催化活性,还需要对一些关键方面进行进一步探索,包括确定表面重构的引发剂和途径、建立结构-性质-活性的相关性,以及对催化剂表面重构进行原位战略性操作。本视角侧重于了解基于 PBA 的前催化剂通过表面重构转化为催化剂表面活性层的过程。重点介绍了 PBA 催化剂在推动电化学能源系统方面取得的最新进展。这一视角将引导该领域的新进入者了解表面转化过程,从而建立结构-性能-活性关系,进而开发出高效的基于 PBA 的电催化剂。
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来源期刊
Chemical Physics Impact
Chemical Physics Impact Materials Science-Materials Science (miscellaneous)
CiteScore
2.60
自引率
0.00%
发文量
65
审稿时长
46 days
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