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Bridging the Gap between SERS Enhancement and Reproducibility by Salt Aggregated Silver Nanoparticles

Silver colloid based nanostructures are a very common means of achieving strong SERS signals. This is due to the hot spots that are formed in between the nanoparticles, as well as their ease of synthesis. They are frequently dismissed, however, as irreproducible when compared to other metal nanostru...

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Bibliographic Details
Published in:Nanomaterials and Nanotechnology 2015-02, Vol.5 (Godište 2015), p.1
Main Authors: Mehigan, Sam, Smyth, Ciarán A., McCabe, Eithne M.
Format: Article
Language:English
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Summary:Silver colloid based nanostructures are a very common means of achieving strong SERS signals. This is due to the hot spots that are formed in between the nanoparticles, as well as their ease of synthesis. They are frequently dismissed, however, as irreproducible when compared to other metal nanostructures, due to the random nature of their formation in a solution. Silver nanoparticle substrates or carefully constructed arrays can be made to be uniform, but they often require a large amount of time to produce, as well as expensive equipment. We will show that by making some adjustments to the experimental setup, silver colloids that have been aggregated to form large flakes can offer both the enhancement factor and reproducibility of many other more expensive and complicated SERS techniques. Silver colloids aggregated into large flake-like structures have been investigated for their surface-enhanced Raman spectroscopy (SERS) properties. These flakes have been imaged using scanning electron microscopy (SEM) and have also been characterized using UV/Vis spectroscopy. They have been highlighted as a cheap and simple means or achieving large Raman enhancement with strong reproducibility, especially when compared to many common methods of substrate fabrication that are more difficult to fabricate. Detection of Rhodamine 6G at a concentration of 5×10−13M has been achieved, as well as xanthopterin at a concentration of 5×10−9M.
ISSN:1847-9804
1847-9804
DOI:10.5772/60125