高灵敏度的气相爆炸物检测：基于发光的微孔聚合物网络。

Highly sensitive gas-phase explosive detection by luminescent microporous polymer networks.

机构信息

Institute of Electronic Devices, University of Wuppertal, Rainer-Gruenter-Str. 21, 42119 Wuppertal, Germany.

University of Wuppertal, Macromolecular Chemistry, Gaußstr. 20, 42119 Wuppertal, Germany.

出版信息

Sci Rep. 2016 Jul 4;6:29118. doi: 10.1038/srep29118.

DOI:10.1038/srep29118

PMID:27373905

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4931441/

Abstract

We propose microporous networks (MPNs) of a light emitting spiro-carbazole based polymer (PSpCz) as luminescent sensor for nitro-aromatic compounds. The MPNs used in this study can be easily synthesized on arbitrarily sized/shaped substrates by simple and low-cost electrochemical deposition. The resulting MPN afford an extremely high specific surface area of 1300 m(2)/g, more than three orders of magnitude higher than that of the thin films of the respective monomer. We demonstrate, that the luminescence of PSpCz is selectively quenched by nitro-aromatic analytes, e.g. nitrobenzene, 2,4-DNT and TNT. In striking contrast to a control sample based on non-porous spiro-carbazole, which does not show any luminescence quenching upon exposure to TNT at levels of 3 ppm and below, the microporous PSpCz shows a clearly detectable response even at TNT concentrations as low as 5 ppb, clearly demonstrating the advantage of microporous films as luminescent sensors for traces of explosive analytes. This level states the vapor pressure of TNT at room temperature.

摘要

我们提出了一种基于发光螺环咔唑聚合物（PSpCz）的微孔网络（MPNs），作为用于检测硝基芳香族化合物的荧光传感器。在这项研究中使用的 MPNs 可以通过简单且低成本的电化学沉积在任意大小/形状的衬底上轻松合成。所得到的 MPN 提供了极高的比表面积 1300m²/g，比各自单体的薄膜高三个数量级以上。我们证明，PSpCz 的发光可以被硝基芳香族分析物（例如硝基苯、2,4-DNT 和 TNT）选择性地猝灭。与基于非多孔螺环咔唑的对照样品形成鲜明对比的是，该对照样品在 3ppm 及以下的 TNT 暴露下没有任何发光猝灭，而微孔 PSpCz 即使在低至 5ppb 的 TNT 浓度下也表现出明显可检测的响应，这清楚地证明了微孔薄膜作为痕量爆炸物分析物的荧光传感器的优势。这个水平是室温下 TNT 的蒸气压。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/4c5f/4931441/a663b74e7e52/srep29118-f1.jpg

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高灵敏度的气相爆炸物检测：基于发光的微孔聚合物网络。

Highly sensitive gas-phase explosive detection by luminescent microporous polymer networks.

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