Fabrication of Silver Nanostructures in the Form of Particles, Dendrites and Flowers on Silicon for Use in SERS Substrates

Cao Dao Tran, Ngan Luong Truc Quynh, Tuan Anh Cao, Minh Kieu Ngoc
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Abstract

Surface Enhanced Raman Scattering (SERS) is a technique that is increasingly being used to detect trace amounts of various types of molecules, especially organic and biological molecules. The SERS effect is available mainly due to the SERS substrate - a noble metal surface that is rough at the nano level or a set of noble metal nanoparticles in a certain arrangement. Such a SERS substrate acts as an analyte Raman signal amplifier and can provide amplification up to millions of times and even more. The amplification coefficient of the SERS substrate is determined mainly by the number of ‘hot spots’ it contains as well as the ‘hotness’ of these spots. In turn, a ‘hot spot’ is a certain space around the tips or a nanogap between particles, where the local electromagnetic field is intensely enhanced, while the ‘hotness’ is determined by the sharpness of the tips (the sharper the hotter) and tightness of the gaps (the narrower the hotter). This report presents an overview of the research results of fabricating a type of SERS substrate with a high enhancement factor, which is the SERS substrate made from silver nanostructures coated on the silicon surface. With the aim of increasing the number of ‘hot spots’ and their quality, as well as ensuring uniformity and reproducibility of the SERS substrate, silver nanostructures have been fabricated in various forms, such as nanoparticles, nanodendrites and nanoflowers. In addition, the report also mentions the use of the above silver nanostructures as SERS substrates to detect trace amounts of some pesticides and other toxic agents such as paraquat, pyridaben, thiram, cyanide...
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在硅上制备用于SERS衬底的粒子、枝晶和花状银纳米结构
表面增强拉曼散射(SERS)是一种越来越多地被用于检测痕量的各种类型的分子,特别是有机和生物分子的技术。SERS效应的产生主要是由于SERS衬底——在纳米水平上粗糙的贵金属表面或一组按一定排列的贵金属纳米颗粒。这种SERS衬底作为分析物拉曼信号放大器,可以提供高达数百万倍甚至更多的放大。SERS衬底的放大系数主要由其包含的“热点”数量以及这些热点的“热度”决定。反过来,“热点”是尖端周围的一定空间或粒子之间的纳米间隙,在那里局部电磁场被强烈增强,而“热度”是由尖端的锋利度(越锋利越热)和间隙的紧密度(越窄越热)决定的。本文综述了制备一种具有高增强因子的SERS衬底的研究成果,即在硅表面涂覆银纳米结构的SERS衬底。为了增加“热点”的数量和质量,以及确保SERS衬底的均匀性和可重复性,银纳米结构以各种形式被制造出来,如纳米颗粒、纳米枝晶和纳米花。此外,报告还提到使用上述银纳米结构作为SERS底物来检测痕量的农药和其他有毒物质,如百草枯、嘧螨虫、噻美姆、氰化物……
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