Resonant Nonplasmonic Nanoparticles for Efficient Temperature-Feedback Optical Heating

Zograf, George; Petrov, Mihail; Zuev, Dmitry; Dmitriev, Pavel; Milichko, Valentin A.; Makarov, Sergey; Belov, Pavel A.

doi:10.1021/acs.nanolett.7b00183

Cited by 127 publications

(135 citation statements)

References 49 publications

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“…Zograf et al recently demonstrated that in Si nanoparticles the optical field localization at magnetic quadrupolar resonance is able to generate a remarkable optical heating, despite its imaginary part of refractive index is two orders of magnitude lower than that of metals. 28 Our study corroborates those observations and provides new insights into opto-thermal management of Si-based systems, demonstrating that the local heating can be increased beyond the melting point of refractory materials. On the other hand, we also demonstrated that thermally-robust beads with outstanding…”

supporting

confidence: 85%

Non-Plasmonic SERS with Silicon: Is It Really Safe? New Insights into Opto-Thermics of Core/Shell Microbeads

Bontempi¹,

Vassalini²,

Danesi³

et al. 2018

Preprint

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Resonant Laser PrintingAll-dielectric and semiconductor-based optical antennas are intensively investigated as promising substrates for surface enhanced Raman scattering (SERS). 1 This emerging interest stems from several factors. One is the possibility to exploit a rich variety of opportunities to tune the Raman response. For example, the chemical enhancement can be widely modulated by controlling charge transfer and adsorption-induced changes of the molecular polarizability of a given analyte.In parallel, the electromagnetic enhancement can take advantage of Mie-type resonances, light trapping and related optical effects to increase sensitivity and selectivity of the Raman response.Further major benefits of non-plasmonic SERS are low-invasiveness (plasmonic heating and plasmon-driven catalysis are avoided) 2-6 and high reproducibility, which make dielectrics more advantageous than metals for many types of Raman analysis, including the real-time monitoring of chemical reactions. These hallmarks are ultimately related to the lossless nature of dielectrics, which avoids the generation of strong local heating under light irradiation. Among the different types of dielectrics and semiconductors that have been proposed so far, SiO 2 /TiO 2 core/shell beads (T-rex) 7 demonstrated unique performances in sensing environmental pollutants and biomarkers. 6-10In particular, micron-sized beads can be individually visualized by optical microscopy and exploited as Mie resonators able to act as all-in-one colloidal platforms combining SERS, mass spectrometry and optical sensing. 11 As the SERS efficiency of these resonators is closely related to the refractive index contrast between core and shell, the replacement of the TiO 2 with a higher index material could further improve the performance of these systems. 12 In this regard, Si represents a natural choice in terms of high refractive index (n∼4 at the most common Raman exciting wavelengths) and compatibility with sensing devices. [13][14][15] Maier and co-workers demonstrated that dimers of spheres and nanodisks, either made of GaP or Si, are able to produce a good near-field enhancement, yet with minimal heating losses if compared with the analogous gold counterparts. (100) substrates by rf-magnetron sputtering and selected for the study (details in Supporting Information, SI 1 and SI 2). The laser spot size of the three wavelengths is commensurate with the 2 µm-sized beads, which enables a geometrically efficient light in-coupling. On the other hand, the laser spot size is about 1/3 of that of the whole sphere in the case of∼ 6.5 µm-sized cores. Both single beads and three-dimensional (3D) colloidal crystals were analysed. ) Raman spectra of the samples before (blue) and after (red) 500s of exposure to an exciting laser beam (laser wavelength: 633 nm, power: 5mW); c) 6_Si100 and d) 2_Si100 samples: e) Raman intensity ratio (IαSi/IcSi) as function of time respectively for 6_Si100 (pink) and for 2_Si100 (light blue); f) Threshold laser power as function of shell thickness...

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supporting

confidence: 85%

Non-Plasmonic SERS with Silicon: Is It Really Safe? New Insights into Opto-Thermics of Core/Shell Microbeads

Bontempi¹,

Vassalini²,

Danesi³

et al. 2018

Preprint

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“…All‐dielectric NPs and nanostructures promote optical field localization near the surface and redirection of light to biomolecules that interact poorly with light. It also should be noted that such NPs are promising candidates for bioimaging , biosensing and heat therapy . In addition, most all‐dielectric NPs are rapidly bio‐degradable and relatively non‐toxic .…”

Section: Resultsmentioning

confidence: 99%

“…In addition, most all‐dielectric NPs are rapidly bio‐degradable and relatively non‐toxic . However, few available reports on biophotonic applications of such NPs have not addressed potential conformational changes in biomolecules adsorbed on their surface.…”

Section: Resultsmentioning

confidence: 99%

“…For light‐induced heating of NP‐biomolecule complexes, we followed a recently developed strategy to heat all‐dielectric NPs by light involving a regime with temperature feedback . As has been shown, the specific sizes of our NPs allowed resonant interaction with light, while the non‐zero imaginary part of its permittivity promoted light absorption and conversion of photon energy to heating up to 1200 K .…”

Section: Resultsmentioning

confidence: 99%

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The conformation of bovine serum albumin adsorbed to the surface of single all‐dielectric nanoparticles following light‐induced heating

Krasilin

Volodina

Sukhova

et al. 2018

Journal of Biophotonics

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Interaction between nanoparticles and biomolecules leads to the formation of biocompatible or bioadverse complexes. Despite the rapid development of nanotechnologies for biology and medicine, relatively little is known about the structure of such complexes. Here, we report on the changes in conformation of a blood protein (bovine serum albumin) adsorbed on the surface of single all-dielectric nanoparticles (silicon and germanium) following light-induced heating to 640 K. This protein is considerably more resistant to heat when adsorbed on the nanoparticle than when in solution or in the solid state. Intriguingly, with germanium nanoparticles this heat resistance is more pronounced than with silicon. These observations will facilitate biocompatible usage of all-dielectric nanoparticles.

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“…Such nanostructures have recently revealed many features, which previously were available only for the plasmonic counterparts. Examples include single-molecule sensing [5,6], efficient harmonic generation [7][8][9], and, among others, photothermal activity [10]. This progress has stimulated the development of all-dielectric photonic devices, including nanoantennas, metasurfaces and optical interconnects [1,3,4].…”

Section: Introductionmentioning

confidence: 99%

Enhancement of Raman scattering in dielectric nanostructures with electric and magnetic Mie resonances

et al. 2018

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Resonantly enhanced Raman scattering in dielectric nanostructures has been recently proven to be an efficient tool for developing nanothermometry and experimental determination of their modecomposition. In this paper, we develop a rigorous analytical theory based on the Green's function approach to calculate the Raman emission from crystalline high-index dielectric nanoparticles. As an example, we consider silicon nanoparticles which have a strong Raman response due to active optical phonon modes. We relate enhancement of Raman signal emission to Purcell effect due to the excitation of Mie modes inside the nanoparticles. We also employ the numerical approach to the calculation of inelastic Raman emission in more sophisticated geometries, which do not allow a straightforward analytical form of the Green's function description. The Raman response from a silicon nanodisk has been analyzed within the proposed method, and the contribution of the various Mie modes has been revealed.

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Resonant Nonplasmonic Nanoparticles for Efficient Temperature-Feedback Optical Heating

Cited by 127 publications

References 49 publications

Non-Plasmonic SERS with Silicon: Is It Really Safe? New Insights into Opto-Thermics of Core/Shell Microbeads

Non-Plasmonic SERS with Silicon: Is It Really Safe? New Insights into Opto-Thermics of Core/Shell Microbeads

The conformation of bovine serum albumin adsorbed to the surface of single all‐dielectric nanoparticles following light‐induced heating

Enhancement of Raman scattering in dielectric nanostructures with electric and magnetic Mie resonances

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