Rational design and synthesis of excavated trioctahedral Au nanocrystalsElectronic supplementary information (ESI) available. See DOI: 10.1039/c5nr02017d

Excavated polyhedral nanostructures, possessing the features of high surface area and well-defined surface structure with a specific crystal facet and avoidance of aggregation, could be one of the best choices for the purpose of reducing consumption and improving performance of noble metals in many...

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Main Authors: Chen, Qiaoli, Jia, Yanyan, Shen, Wei, Xie, Shuifen, Yang, Yanan, Cao, Zhenming, Xie, Zhaoxiong, Zheng, Lansun
Format: Article
Language:English
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Summary:Excavated polyhedral nanostructures, possessing the features of high surface area and well-defined surface structure with a specific crystal facet and avoidance of aggregation, could be one of the best choices for the purpose of reducing consumption and improving performance of noble metals in many application fields. However, the formation of the excavated structures is thermodynamically unfavourable and its rational synthesis is far beyond our knowledge. In this work, taking overgrowth of Pd onto trioctahedral Au nanocrystals as a model, we present a deep insight study for synthesizing an excavated structure relying on the protection role of surfactants under suitable crystal growth kinetics. Based on the abovementioned understanding, we designed a simple and effective strategy to synthesize Au nanocrystals with excavated trioctahedral structure in one step. Due to the novel feature of the excavated structure and exposed high energy {110} facets, excavated trioctahedral Au NCs exhibited optical extinction at the near-infrared region and showed high catalytic activity towards the reduction of p -nitrophenol. Moreover, the synthetic strategy can be extended to the synthesis of excavated Au-Pd alloys. Excavated trioctahedral Au nanocrystals were rationally designed and synthesized via a one-step chemical route.
ISSN:2040-3364
2040-3372
DOI:10.1039/c5nr02017d