Silent enhancement of SERS signal without increasing hot spot intensities

Postacı, Selen; Yildiz, Bilge Can; Bek, Alpan; Tașgın, Mehmet Emre

doi:10.1515/nanoph-2018-0089

Cited by 23 publications

(14 citation statements)

References 61 publications

(75 reference statements)

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“…In order to provide experimental proof of the influence of average local field enhancement on our fabricated SERS substrates, experiments using CV as analyte were performed (Fig. 4(A)), as described above (although we do emphasize that local field enhancement is not the only mechanism underlying observed SERS enhancements [48,49]). The experimentally determined EF values for subsequent fabrication steps are shown in Fig.…”

Section: Sers Enhancement Factor From Experimentsmentioning

confidence: 99%

Gold nanoisland substrates for SERS characterization of cultured cells

Milewska¹,

Živanović²,

Merk³

et al. 2019

Biomed. Opt. Express

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We demonstrate a simple approach for fabricating cell-compatible SERS substrates, using repeated gold deposition and thermal annealing. The substrates exhibit SERS enhancement up to six orders of magnitude and high uniformity. We have carried out Raman imaging of fixed mesenchymal stromal cells cultured directly on the substrates. Results of viability assays confirm that the substrates are highly biocompatible and Raman imaging confirms that cell attachment to the substrates is sufficient to realize significant SERS enhancement of cellular components. Using the SERS substrates as an in vitro sensing platform allowed us to identify multiple characteristic molecular fingerprints of the cells, providing a promising avenue towards non-invasive chemical characterization of biological samples.

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Section: Sers Enhancement Factor From Experimentsmentioning

confidence: 99%

Gold nanoisland substrates for SERS characterization of cultured cells

Milewska¹,

Živanović²,

Merk³

et al. 2019

Biomed. Opt. Express

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“…Besides facilitating the movements in CR imaging, MNSs also provided a medium for observing plasmon analogs [10] of electromagnetically-induced transparency (EIT)-like effects [26][27][28], originally observed for three or more level atoms [29][30][31]. Fano resonances [26,27,32], plasmon-analog of EIT, and nonlinear response enhancement [33][34][35][36] have been demonstrated in MNSs. Very recently, the plasmon-analog of refractive index enhancement was finally also demonstrated via simple analytical calculations which are supported by the exact solutions of the three-dimensional (3D) Maxwell equations [37].…”

Section: Introductionmentioning

confidence: 99%

Continuously-tunable Cherenkov-radiation-based detectors via plasmon index control

2020

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A recent study [PRB 100, 075427 (2019)], finally, demonstrated the plasmon-analog of refractive index enhancement in metal nanostructures (MNSs), which has already been studied in atomic clouds for several decades. Here, we simply utilize this phenomenon for achieving continuously-tunable enhanced Cherenkov radiation (CR) in MNSs. Beyond enabling CR from slow-moving particles, or increasing its intensity, the phenomenon can be used in continuous-tuning of the velocity cutoff of particles contributing to CR. More influentially, this allows a continuously-tunable analysis of the contributing particles as if the data is collected from many different detectors, which enables data correction. The phenomenon can also be integrated into lattice MNSs, for continuous medium tuning, where a high density of photonic states is present and the threshold for the CR can even be lifted. Additionally, vanishing absorption can heal radiation angle distortion effects caused by the metallic absorption.

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“…Localization also strengthens the nonlinear properties of molecules positioned in the vicinity of the hot spots. Signal from a Raman-reporter molecule can be enhanced remarkably (6 ). Such a great increase in the signal results from the localization of both the incident and the produced (Raman) fields (7 ).…”

Section: Introductionmentioning

confidence: 99%

“…The scheme we use, a novel scheme to our best knowledge, enhances the hot spot field intensity in the steady-state, which also leads to enhancement in the second harmonic field intensity. Next, we use a path interference scheme (6 ) which enhances only (ii ) the nonlinear response without increasing the hot spot field intensity. This method can be useful when MNP-QE hybrid system is excited with a strong pulsed laser.…”

Section: Introductionmentioning

confidence: 99%

Controlling steady-state second harmonic signal via linear and nonlinear Fano resonances

Günay

Artvin

Bek

et al. 2018

Journal of Modern Optics

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Nonlinear signal even from a single molecule becomes visible at hot spots of plasmonic nanoparticles. In these structures, Fano resonances can control the nonlinear response in two ways. (i) A linear Fano resonance can enhance the hot spot field, resulting enhanced nonlinear signal. (ii) A nonlinear Fano resonance can enhance the nonlinear signal without enhancing the hot spot. In this study, we compare the enhancement of second harmonic signal at the steady-state obtained via these two methods. Since we are interested in the steady-state signal, we adapt a linear enhancement which works at the steady-state. This is different than the dark-hot resonances that appears in the transparency window due to enhanced plasmon lifetime.

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Silent enhancement of SERS signal without increasing hot spot intensities

Cited by 23 publications

References 61 publications

Gold nanoisland substrates for SERS characterization of cultured cells

Gold nanoisland substrates for SERS characterization of cultured cells

Continuously-tunable Cherenkov-radiation-based detectors via plasmon index control

Controlling steady-state second harmonic signal via linear and nonlinear Fano resonances

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