Ultrafine Pt‐Based Nanowires for Advanced Catalysis

At the frontier of electrocatalysis and heterogeneous reactions, significant effort has been devoted to Pt‐based nanomaterials owing to their advantages of tunable morphology and excellent catalytic properties. In contrast to Pt‐based nanocatalysts with other morphologies, nanowire catalysts, especi...

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Bibliographic Details
Published in:Advanced functional materials 2020-07, Vol.30 (28), p.n/a
Main Authors: Xu, Hui, Shang, Hongyuan, Wang, Cheng, Du, Yukou
Format: Article
Language:English
Subjects:
Catalysis
Catalysts
Crystal structure
energy conversion
Isotropy
Materials science
Morphology
Nanomaterials
Nanowires
Ripening
Selectivity
Solid phases
Structural stability
ultrafine Pt‐based nanowires
Ultrafines
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Summary:At the frontier of electrocatalysis and heterogeneous reactions, significant effort has been devoted to Pt‐based nanomaterials owing to their advantages of tunable morphology and excellent catalytic properties. In contrast to Pt‐based nanocatalysts with other morphologies, nanowire catalysts, especially 1D ultrafine nanowire (NW) structure, are garnering increased attention because of their advantages of high atomic efficiency, intrinsic isotropy, rich high‐index facets, better conductivity, robust structure stability for prohibiting dissolution, ripening, and aggregation. Regardless of these advantages, it is still challenging to realize the precise control of ultrafine Pt‐based NWs in terms of their size, crystal phase structure, and composition. Aiming to synthesize advanced ultrafine Pt‐based NWs catalysts with higher activity, durability, and selectivity toward catalytic reactions, this review summarizes the recently available approaches for improving the catalytic performance of ultrafine Pt‐based NWs with detailed guidance. A summary of recent progress in ultrafine Pt‐based NWs catalysts for advanced catalysis and heterogeneous reactions is also provided. Furthermore, integrated experimental and theoretical studies are reviewed to explain the activity, stability, and selectivity enhancement mechanism. In the final section, the challenges and outlook are also discussed to provide guidance for the rational engineering of efficient ultrafine Pt‐based NWs catalysts for applications in renewable‐energy‐related devices. Recent progress in advanced catalysis promoted by ultrafine platinum‐based nanowires is summarized with focus on geometric and electronic structure engineering including strain, facet, synergistic role, and electronic property engineering. Existing challenges and future development directions to obtain more credible Pt‐based electrocatalysts are highlighted.
ISSN:1616-301X
1616-3028
DOI:10.1002/adfm.202000793