2015
DOI: 10.1021/acsnano.5b03624
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Metal-Enhanced Near-Infrared Fluorescence by Micropatterned Gold Nanocages

Abstract: In metal-enhanced fluorescence (MEF), the localized surface plasmon resonances of metallic nanostructures amplify the absorption of excitation light and assist in radiating the consequent fluorescence of nearby molecules to the far-field. This effect is at the base of various technologies that have strong impact on fields such as optics, medical diagnostics, and biotechnology. Among possible emission bands, those in the near-infrared (NIR) are particularly intriguing and widely used in proteomics and genomics … Show more

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Cited by 102 publications
(86 citation statements)
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“…The high-energy charges will transfer from the S * to S 0 directly, increasing the probability of recombination between the electrons and the holes. This charge transfer process will highly enhance the fluorescence radiation in R6G 44, 45 . This analysis above gives a reasonable explanation to the relationship between the thickness of shells and fluorescence noises observed in experiments.
Figure 9Schematic diagram of the surface resonance charge transfer.
…”
Section: Resultsmentioning
confidence: 98%
“…The high-energy charges will transfer from the S * to S 0 directly, increasing the probability of recombination between the electrons and the holes. This charge transfer process will highly enhance the fluorescence radiation in R6G 44, 45 . This analysis above gives a reasonable explanation to the relationship between the thickness of shells and fluorescence noises observed in experiments.
Figure 9Schematic diagram of the surface resonance charge transfer.
…”
Section: Resultsmentioning
confidence: 98%
“…Most previous work on MEF, however, has focused on fluorophores emitting in the visible region, with only a limited number of studies investigating the NIR. 18,20,[25][26][27] Recently, gold (Au) nanocages microprinted into a defined structure with spatial control, allowed fluorescence enhancement in the NIR, but only by a factor of ~2-7. 26 Indeed, most of the recent work for the fluorescent enhancement of NIR dyes has been based on Au or silver (Ag) nanostructures, including nanorods, nanoshells and porous films obtained by dealloying.…”
Section: Introductionmentioning
confidence: 99%
“…18,20,[25][26][27] Recently, gold (Au) nanocages microprinted into a defined structure with spatial control, allowed fluorescence enhancement in the NIR, but only by a factor of ~2-7. 26 Indeed, most of the recent work for the fluorescent enhancement of NIR dyes has been based on Au or silver (Ag) nanostructures, including nanorods, nanoshells and porous films obtained by dealloying. 10,18 For instance, NIR protein microarrays on porous Au films have been employed for multiplexed detection of disease biomarkers.…”
Section: Introductionmentioning
confidence: 99%
“…Silver and gold nanostructures exhibit plasmon absorption in a range from the visible to near infrared and have been widely applied in MEF‐based fluorescent platforms . A variety of metal nanostructures, such as spherical silver nanoparticles, silver nanocubes, spherical gold nanoparticles, gold nanocages, and multi‐branched gold nanoparticles with different plasmon absorptions have been used as magnifying metal nanostructures. Dendritic silver clusters on p‐silicon wafers have been developed by our group, and these structures achieved a 25‐fold enhancement in porphyrin fluorescence intensity .…”
Section: Mef‐based Fluorescent Platformsmentioning
confidence: 99%