Portable smart films for ultrasensitive detection and chemical analysis using SERS and SERRS

Cabrera, Flávio Camargo; Aoki, Pedro H.B.; Aroca, Ricardo F.; Constantino, Carlos J. L.; Santos, David S. dos; Job, Aldo Eloízo

doi:10.1002/jrs.3074

Cited by 30 publications

(26 citation statements)

References 36 publications

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“…This strategy generates nanocomposites whose morphology can vary, such as in a polymeric shell and a metal core [60,61,77,96,102], a polymeric core and a metal shell [95] or a polymeric matrix having dispersed metallic fillers [68,69,97]. In particular cases, the polymer can act as reducing agent due to specific functional groups, avoiding the use of an external reducing agent [61,73]. The advantages of this one-step approach relies on its simplicity, although the resulting nanocomposites may exhibit inhomogeneity in terms of morphology and fillers distribution in the polymer matrix [10,129].…”

Section: Chemical Reduction (In Situ Method)mentioning

confidence: 99%

“…example, Brust and co⁻workers have described the preparation of Ag loaded agarose hydrogels, in which the metallic nanofillers are trapped inside the polymer network due to the agarose capability to dry and rehydrate. In this particular case, the use of agarose as polymeric matrix provides the formation of a recyclable SERS substrate, in which the 1-naphthalenethiol used as analyte can be washed out by dialysis and the composite can be reused again [60] Nanocomposites containing gelatin [61,76,77], natural rubber [73] and distinct synthetic polymers [98][99][100][101] have been also prepared using in situ methods. For instance, Wu and his team have reported the fabrication of Ag loaded poly(styrene) microspheres using the chemical reduction method for the SERS detection of organic molecules such as dyes.…”

Section: Raman Spectroscopymentioning

confidence: 99%

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SERS Research Applied to Polymer Based Nanocomposites

Fateixa¹,

Nogueira²,

Trindade³

2018

Raman Spectroscopy

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Polymer based nanocomposites containing metal nanoparticles (e.g. Au, Ag) have gained increased attention as a new class of SERS (Surface Enhanced Raman Scattering) substrates for analytical platforms. On the other hand, the application of SERS using such platforms can also provide new insights on the properties of composite materials. In this chapter, we review recent research on the development of SERS substrates based on polymer nanocomposites and their applications in different fields. The fundamentals of SERS are briefly approached and subsequently there is a reference to the strategies of preparation of polymer based nanocomposites. Here the main focus is on SERS studies that have used a diversity of polymer based nanocomposites, highlighting certain properties of the materials that are relevant for the envisaged functionalities. A final section is devoted to the joint use of Raman imaging and SERS in nanocomposites development, a topic that presents a great potential still to be explored as shown by the recent research in this field.

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Section: Chemical Reduction (In Situ Method)mentioning

confidence: 99%

Section: Raman Spectroscopymentioning

confidence: 99%

SERS Research Applied to Polymer Based Nanocomposites

Fateixa¹,

Nogueira²,

Trindade³

2018

Raman Spectroscopy

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“…These images were obtained from natural rubber samples with gold nanoparticles using scanning electron microscopy (SEM). [5,6] presents the green synthesis of gold nanoparticles using natural rubber membranes, an organic component that acts as a reductant/stabilizer. Gold nanoparticles were reduced in natural rubber at different time periods: 6, 9, 15, 30, 60 and 120 min.…”

Section: Dataset Of Photomicrographsmentioning

confidence: 99%

Estimating the concentration of gold nanoparticles incorporated on natural rubber membranes using multi-level starlet optimal segmentation

et al. 2014

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This study consolidates Multi-Level Starlet Segmentation (MLSS) and Multi-Level Starlet Optimal Segmentation (MLSOS), techniques for photomicrograph segmentation that use starlet wavelet detail levels to separate areas of interest in an input image. Several segmentation levels can be obtained using Multi-Level Starlet Segmentation; after that, Matthews correlation coefficient (MCC) is used to choose an optimal segmentation level, giving rise to Multi-Level Starlet Optimal Segmentation. In this paper, MLSOS is employed to estimate the concentration of gold nanoparticles with diameter around 47 nm, reducted on natural rubber membranes. These samples were used on the construction of SERS/SERRS substrates and in the study of natural rubber membranes with incorporated gold nanoparticles influence on Leishmania braziliensis physiology. Precision, recall and accuracy are used to evaluate the segmentation performance, and MLSOS presents accuracy greater than 88% for this application.

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“…In fact, latest years have witnessed growing interest in the fabrication of flexible plasmonic substrates for noninvasive sensing. The research on flexible plasmonics is quickly moving toward the fabrication of low‐cost devices for daily‐life applications and recent studies have reported the fabrication of flexible SERS substrates made of membranes of natural rubber and polydimethylsiloxane containing gold nanoparticles, of silver nanoparticles embedded in polycarbonate plastic films and of hard thermoplastic polymers coated by thin gold or silver layers by sputtering and electroless deposition …”

Section: Introductionmentioning

confidence: 99%

Laser‐induced surface structures on gold‐coated polymers: Influence of morphology on surface‐enhanced Raman scattering enhancement

Rebollar

Hernández

Sanz

et al. 2015

J of Applied Polymer Sci

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The fabrication of highly sensitive and reproducible substrates for Surface-Enhanced Raman Scattering (SERS) remains a challenging scientific and technological issue. In this work, laser-induced periodic surface structures are generated on poly(trimethylen terephthalate) films upon laser irradiation with the linearly polarized beams of a Nd:YAG laser (4th harmonic, 266 nm), an ArF excimer laser (193 nm), and a Titanium:sapphire laser (795 nm), resulting in periods close to the laser wavelength when irradiating at normal incidence, and larger periods for different angles of incidence. Additional irradiation with a circularly polarized beam at 266 nm produces superficial circular structures. The nanostructured polymers are coated with a nanoparticle assembled gold layer by pulsed laser deposition at 213 nm. The capabilities of these substrates for SERS are evaluated using benzenethiol as a test molecule and different degrees of Raman signal enhancement are observed depending on the nanostructure type. The highest enhancement factor is obtained by for nanostructured substrates with the highest values of period, depth, and roughness.

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Portable smart films for ultrasensitive detection and chemical analysis using SERS and SERRS

Cited by 30 publications

References 36 publications

SERS Research Applied to Polymer Based Nanocomposites

SERS Research Applied to Polymer Based Nanocomposites

Estimating the concentration of gold nanoparticles incorporated on natural rubber membranes using multi-level starlet optimal segmentation

Laser‐induced surface structures on gold‐coated polymers: Influence of morphology on surface‐enhanced Raman scattering enhancement

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