银掺杂的 Ag(x)Au(25-x) 纳米团簇的光致发光量子产率提高 200 倍：第 13 个银原子起关键作用。

A 200-fold quantum yield boost in the photoluminescence of silver-doped Ag(x)Au(25-x) nanoclusters: the 13th silver atom matters.

机构信息

Department of Chemistry, Anhui University, Hefei, Anhui 230601 (China).

出版信息

Angew Chem Int Ed Engl. 2014 Feb 24;53(9):2376-80. doi: 10.1002/anie.201307480. Epub 2014 Jan 28.

DOI:10.1002/anie.201307480

Abstract

The rod-shaped Au25 nanocluster possesses a low photoluminescence quantum yield (QY=0.1%) and hence is not of practical use in bioimaging and related applications. Herein, we show that substituting silver atoms for gold in the 25-atom matrix can drastically enhance the photoluminescence. The obtained Ag(x)Au(25-x) (x=1-13) nanoclusters exhibit high quantum yield (QY=40.1%), which is in striking contrast with the normally weakly luminescent Ag(x)Au(25-x) species (x=1-12, QY=0.21%). X-ray crystallography further determines the substitution sites of Ag atoms in the Ag(x)Au(25-x) cluster through partial occupancy analysis, which provides further insight into the mechanism of photoluminescence enhancement.

摘要

棒状的 Au25 纳米团簇的光致发光量子产率（QY=0.1%）较低，因此在生物成像和相关应用中没有实际用途。在此，我们证明了在 25 个原子的基质中用银原子取代金原子可以显著增强光致发光。所得到的 Ag(x)Au(25-x)（x=1-13）纳米团簇表现出高的量子产率（QY=40.1%），这与通常弱发光的 Ag(x)Au(25-x)物种（x=1-12，QY=0.21%）形成鲜明对比。通过部分占据分析，X 射线晶体学进一步确定了 Ag(x)Au(25-x)团簇中 Ag 原子的取代位置，这为光致发光增强的机制提供了进一步的见解。

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银掺杂的 Ag(x)Au(25-x) 纳米团簇的光致发光量子产率提高 200 倍：第 13 个银原子起关键作用。

A 200-fold quantum yield boost in the photoluminescence of silver-doped Ag(x)Au(25-x) nanoclusters: the 13th silver atom matters.

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