Coupled Plasmon Modes in 2D Gold Nanoparticle Clusters and Their Effect on Local Temperature Control

Borah, Rituraj; Verbruggen, Sammy W.

doi:10.1021/acs.jpcc.9b09048

Cited by 45 publications

(49 citation statements)

References 73 publications

(161 reference statements)

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“…; the enhanced absorption and reduction of scattering due to Au incorporation is certainly advantageous for photothermal applications. 64 Likewise, the widening of the spectra in the case of core-shell nanoparticles provides a wider window of usable wavelengths. A large 60 nm Ag nanoparticle with high radiative loss and low absorption does not reach a maximum photothermal steady state temperature as high as a pure Au nanoparticle of the same size.…”

Section: Photothermal Effectmentioning

confidence: 99%

Silver–Gold Bimetallic Alloy versus Core–Shell Nanoparticles: Implications for Plasmonic Enhancement and Photothermal Applications

Borah

Verbruggen

2020

J. Phys. Chem. C

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Bimetallic plasmonic nanoparticles enable tuning of the optical response and chemical stability by variation of the composition. The present numerical simulation study compares Ag-Au alloy, Ag@Au core-shell, and Au@Ag core-shell bimetallic plasmonic nanoparticles of both spherical and anisotropic (nanotriangle and nanorods) shapes. By studying both spherical and anisotropic (with LSPR in the near-infrared region) shapes, cases with and without interband transitions of Au can be decoupled. Explicit comparisons are facilitated by numerical models supported by careful validation and examination of optical constants of Au-Ag alloys reported in literature. Although both Au-Ag core-shell and alloy nanoparticles exhibit an intermediary optical response between that of pure Ag and Au nanoparticles, there are noticeable differences in the spectral characteristics. Also, the effect of the bimetallic constitution in anisotropic nanoparticles is starkly different from that in spherical nanoparticles due to the absence of Au interband transitions in the former case. In general, the improved chemical stability of Ag nanoparticles by incorporation of Au comes with a cost of reduction in plasmonic enhancement, also applicable to anisotropic nanoparticles with a weaker effect. A photothermal heat transfer study confirms that increased absorption by the incorporation of Au in spherical Ag nanoparticles also results in an increased steady state temperature. On the other hand, anisotropic nanoparticles are inherently better absorbers, hence better photothermal sources and their photothermal properties are apparently not strongly affected by the incorporation of one metal in the other. This study of the optical/spectral and photothermal characteristics of bimetallic Au-Ag alloy versus core-shell nanoparticles provides a detailed physical insight for the development of new taylor-made plasmonic nanostructures.

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Section: Photothermal Effectmentioning

confidence: 99%

Silver–Gold Bimetallic Alloy versus Core–Shell Nanoparticles: Implications for Plasmonic Enhancement and Photothermal Applications

Borah

Verbruggen

2020

J. Phys. Chem. C

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“…Such a large enhancement is achieved by taking advantage of the strong near field generated at the metal-dielectric interface associated The much larger enhancement in the small hexagons could be related to the existence of extended collective plasmonic modes propagating through the entire hexagon. In fact, the possibility of using the inner NP structure as plasmonic interconnection between the different sides of the hexagon could also favor the propagation of the plasmon mode inside the hexagon [47][48][49][50][51]. Additionally, due to the hexagon dimensions, the presence of modes in the wavelength-scale hexagonal nanocavity could also contribute to the light confinement and enhanced light-matter interaction process [52].…”

Section: Discussionmentioning

confidence: 99%

Giant Second Harmonic Generation Enhancement by Ag Nanoparticles Compactly Distributed on Hexagonal Arrangements

2021

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The association of plasmonic nanostructures with nonlinear dielectric systems has been shown to provide useful platforms for boosting frequency conversion processes at metal-dielectric interfaces. Here, we report on an efficient route for engineering light–matter interaction processes in hybrid plasmonic-χ(2) dielectric systems to enhance second harmonic generation (SHG) processes confined in small spatial regions. By means of ferroelectric lithography, we have fabricated scalable micrometric arrangements of interacting silver nanoparticles compactly distributed on hexagonal regions. The fabricated polygonal microstructures support both localized and extended plasmonic modes, providing large spatial regions of field enhancement at the optical frequencies involved in the SHG process. We experimentally demonstrate that the resonant excitation of the plasmonic modes supported by the Ag nanoparticle-filled hexagons in the near infrared region produces an extraordinary 104-fold enhancement of the blue second harmonic intensity generated in the surface of a LiNbO3 crystal. The results open new perspectives for the design of efficient hybrid plasmonic frequency converters in miniaturized devices.

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“…It is also noted that, beside MB and PE effects, electro-optic-effect should also be considered for calculating the overall g 0 for piezoelectric 1 3 material (Javerzac-Galy et al 2016b), and we hope to carry out electro-optic-effect-related work in the near future. The last but not the least, by utilizing acousto-optical modulation (Cai et al 2019;Lio et al 2019a;Oumekloul et al 2020) and photo-thermal effect (Lio et al 2019b;Borah and Verbruggen 2019), the simultaneous confinements of hybrid modes and strong OMC may make our design applicable for non-invasive biological sensing (Salari et al 2018), optomechanically tunable plasmonic heater for drug release and lab-on-chip devices.…”

Section: Optimizations Of G 0 In 2d Hybrid Plasmonicphononic Crystal Cavitymentioning

confidence: 99%

Hybrid plasmonic–phononic cavity design for enhanced optomechanical coupling in lithium niobate

Liu

Bibbò

et al. 2020

Appl Nanosci

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A hybrid plasmonic-phononic cavity design which enables high vacuum coupling rate has been proposed in lithium niobate (LN) phononic crystals (Phncs) that have been perforated by air holes and coated with thin silver film. By tailoring the geometry, optomechanical interaction between the plasmonic modes (produced by the metal/insulator) and the phononic modes (confined by the phononic bandgap effect) is greatly enhanced. Numerical results based on finite-element method (FEM) reveal that in this hybrid plasmonic-phononic design, high vacuum coupling rate that predominantly contributed by moving boundary effect is on the order of 10 6 Hz, which is about one to two orders higher than that contributed by photoelastic effect shown in conventional phoxonic crystal designs. Results evidence how the vacuum coupling rate depends on geometrical parameters like the radius of the defect air hole, the thickness of silver layer, and LN layer. The simultaneous confinement and strong coupling, combined with other advantages as lack of constraint to the refractive index, and integration of piezoelectric material and metal in a chip, this hybrid design may be suitable for non-invasive biological sensing, optomechanically tunable plasmonic heater for drug release and lab-on-chip devices.

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Coupled Plasmon Modes in 2D Gold Nanoparticle Clusters and Their Effect on Local Temperature Control

Cited by 45 publications

References 73 publications

Silver–Gold Bimetallic Alloy versus Core–Shell Nanoparticles: Implications for Plasmonic Enhancement and Photothermal Applications

Silver–Gold Bimetallic Alloy versus Core–Shell Nanoparticles: Implications for Plasmonic Enhancement and Photothermal Applications

Giant Second Harmonic Generation Enhancement by Ag Nanoparticles Compactly Distributed on Hexagonal Arrangements

Hybrid plasmonic–phononic cavity design for enhanced optomechanical coupling in lithium niobate

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