A fundamental comprehension and recent progress in advanced Pt-based ORR nanocatalysts

Today, Pt/C catalysts are widely used in proton exchange membrane fuel cells (PEMFCs). The practical applications of PEMFCs still face many limitations in the preparation of advanced Pt-based catalysts, including high cost, limited life-time, and insufficient power density. A kinetically sluggish oxygen reduction reaction (ORR) is primarily responsible for these issues. The development of advanced Pt-based catalysts is crucial for solving these problems when the large-scale application of PEMFCs is to be realized. Herein, we demonstrate the design principle of advanced Pt-based catalysts with an emphasis on theoretical understandings to practical applications. Generally, three main strategies (including strain effect, electronic effect, and ensemble effect) that governing the initial activity of Pt-based electrocatalysts are elaborated in detail in this review. Recent advanced Pt-based ORR catalysts are summarized and we present representative achievements to further reveal the relationship of excellent ORR performance based on theoretical mechanisms. Then we focus on the preparation standards of membrane electrode assembles and testing protocols in practice. Finally, we predict the remaining challenges and present our perspectives with regards to design strategies for improving ORR performance of Pt-based catalysts in the future.

Automated summary

The article discusses the current use of Pt/C catalysts in PEMFCs and the challenges faced, emphasizing on the design principles of advanced Pt-based catalysts and theoretical mechanisms behind ORR performance. It also includes a summary of recent advanced Pt-based ORR catalysts and practical preparation standards, as well as predictions for future challenges and design strategies to improve ORR performance of Pt-based catalysts.