Nano Archive

Optimization of nanoparticle size for plasmonic enhancement of fluorescence

Stranik, Ondrej and Nooney, Robert and McDonagh, Colette and MacCraith, Brian D. (2007) Optimization of nanoparticle size for plasmonic enhancement of fluorescence. PLASMONICS, 2 (1). pp. 15-22. ISSN 1557-1955 (Print) 1557-1963 (Online)

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Official URL: http://www.springerlink.com/content/v2215727208414...

Abstract

This paper reports on the enhancement of fluorescence that can result from the proximity of fluorophores to metallic nanoparticles (NPs). This plasmonic enhancement, which is a result of the localized surface plasmon resonance at the metal surface, can be exploited to improve the signal obtained from optical biochips and thereby lower the limits of detection. There are two distinct enhancement effects: an increase in the excitation of the fluorophore and an increase in its quantum efficiency. This study focuses on the first of these effects where the maximum enhancement occurs when the NP plasmon resonance wavelength coincides with the fluorophore absorption band. In this case, the excitation enhancement is proportional to the square of the amplitude of the electric field. The scale of the enhancement depends on many parameters, such as NP size and shape, metal type, and NP fluorophore separation. A model system consisting of spherical gold/silver alloy NPs, surrounded by a silica spacer shell, to which is attached a fluorescent ruthenium dye, was chosen and the dependence of the fluorescence enhancement on NP diameter was investigated. Theoretical calculations, based on Mie theory, were carried out to predict the maximum possible enhancement factor for spherical NPs with a fixed composition and a range of diameters. Spherical NPs of the same composition were fabricated by chemical preparation techniques. The NPs were coated with a thin silica shell to overcome quenching effects and the dye was attached to the shell.

Item Type:Article
Uncontrolled Keywords:plasmonic; fluorescence enhancement; metallic nanoparticles
Subjects:Material Science > Nanostructured materials
Material Science > Nanochemistry
ID Code:3290
Deposited By:Farnush Anwar
Deposited On:15 Jan 2009 15:58
Last Modified:28 Jan 2009 16:51

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