Recent Advances in Plasmonic Nanostructures for Enhanced Photocatalysis and Electrocatalysis

Plasmonic nanomaterials coupled with catalytically active surfaces can provide unique opportunities for various catalysis applications, where surface plasmons produced upon proper light excitation can be adopted to drive and/or facilitate various chemical reactions. A brief introduction to the local...

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Vydáno v:Advanced materials (Weinheim) Ročník 33; číslo 6; s. e2000086 - n/a
Hlavní autoři: Li, Siwei, Miao, Peng, Zhang, Yuanyuan, Wu, Jie, Zhang, Bin, Du, Yunchen, Han, Xijiang, Sun, Jianmin, Xu, Ping
Médium: Journal Article
Jazyk:angličtina
Vydáno: Germany Wiley Subscription Services, Inc 01.02.2021
Témata:
Ammonia
Carbon dioxide
catalysis
Chemical reactions
Decomposition reactions
Energy conversion
Energy storage
Heterostructures
Hydrogen evolution reactions
Materials science
Nanomaterials
Nanostructure
Nitrogenation
Oxidation
Oxygen evolution reactions
Oxygen reduction reactions
Photochemical reactions
plasmonic materials
Plasmonics
Plasmons
plasmon‐driven photocatalytic reactions
plasmon‐enhanced electrocatalytic reactions
surface plasmon
catalysis
plasmon-driven photocatalytic reactions
plasmonic materials
plasmon-enhanced electrocatalytic reactions
surface plasmon
ISSN:0935-9648, 1521-4095, 1521-4095
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Shrnutí:Plasmonic nanomaterials coupled with catalytically active surfaces can provide unique opportunities for various catalysis applications, where surface plasmons produced upon proper light excitation can be adopted to drive and/or facilitate various chemical reactions. A brief introduction to the localized surface plasmon resonance and recent design and fabrication of highly efficient plasmonic nanostructures, including plasmonic metal nanostructures and metal/semiconductor heterostructures is given. Taking advantage of these plasmonic nanostructures, the following highlights summarize recent advances in plasmon‐driven photochemical reactions (coupling reactions, O2 dissociation and oxidation reactions, H2 dissociation and hydrogenation reactions, N2 fixation and NH3 decomposition, and CO2 reduction) and plasmon‐enhanced electrocatalytic reactions (hydrogen evolution reaction, oxygen reduction reaction, oxygen evolution reaction, alcohol oxidation reaction, and CO2 reduction). Theoretical and experimental approaches for understanding the underlying mechanism of surface plasmon are discussed. A proper discussion and perspective of the remaining challenges and future opportunities for plasmonic nanomaterials and plasmon‐related chemistry in the field of energy conversion and storage is given in conclusion. The recent advances in applying the surface plasmon resonance effect from plasmonic nanostructures for enhanced photocatalysis and electrocatalysis are comprehensively summarized, highlighting the synthesis strategies of plasmonic nanomaterials along with future directions of plasmon‐related research.
Bibliografie:Dedicated to the 100th anniversary of Harbin Institute of Technology
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ISSN:0935-9648
1521-4095
1521-4095
DOI:10.1002/adma.202000086