Heating or cooling: temperature effects on the synthesis of atomically precise gold nanoclusters

Heating or cooling: temperature effects on the synthesis of atomically precise gold nanoclusters

Developing an efficient, well-controlled synthesis strategy for gold nanoclusters (Au NCs) is crucial for delivering their expected applications in many fields; and such development requires fundamental understandings on the synthetic chemistry. The synthesis of Au NCs typically consists of a pair o...

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Bibliographic Details
Main Authors: Chen, Tiankai, Yao, Qiaofeng, Yuan, Xun, Nasaruddin, Ricca Rahman, Xie, Jianping
Format: Article
Language:English
English
English
Published: American Chemical Society 2017
Subjects:
QD Chemistry
TP155 Chemical engineering
Online Access:http://irep.iium.edu.my/69309/
http://irep.iium.edu.my/69309/
http://irep.iium.edu.my/69309/
http://irep.iium.edu.my/69309/1/69309_Heating%20or%20Cooling.pdf
http://irep.iium.edu.my/69309/2/69309_Heating%20or%20Cooling_SCOPUS.pdf
http://irep.iium.edu.my/69309/3/69309_Heating%20or%20Cooling_WOS.pdf
Description
Summary:Developing an efficient, well-controlled synthesis strategy for gold nanoclusters (Au NCs) is crucial for delivering their expected applications in many fields; and such development requires fundamental understandings on the synthetic chemistry. The synthesis of Au NCs typically consists of a pair of reversible reactions: a fast reduction-growth reaction and a slow size-focusing reaction. Here we demonstrate that the above two reactions can be well-balanced while accelerated in a heated synthesis protocol, thus providing an efficient and scalable synthesis method to obtain thermodynamically favorable Au25(SR)18 NCs (SR denotes thiolate ligand) with high yield (>95% on gold atom basis) and fast kinetics. By investigating the Au NC formation behavior at different temperature, we identified the endothermic nature of the reductive formation of Au25(SR)18 NCs from Au(I)-thiolate complex precursors. More interestingly, if overheated, after the formation of Au25(SR)18, there exists an irreversible first-order reaction, which could transform Au25(SR)18 into Au NCs of mixed sizes. As a result, 40 °C is identified as the optimal temperature to synthesize Au25(SR)18 in aqueous solution, as the half-life of the transformation reaction (67.8 h) is much longer than the time needed to obtain high yield Au25(SR)18. The detailed understandings on the temperature effects of Au NC synthesis would facilitate the development of efficient synthesis strategies for atomically precise Au NCs with predesigned size, composition and structure.

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