Effect of Surface Scattering of Electrons on Ratios of Optical Absorption and Scattering to Extinction of Gold Nanoshell

Ye, Yiyang; Chen, T. P.; Liu, Zhen; Yuan, Xiaochen

doi:10.1186/s11671-018-2670-7

Cited by 15 publications

(16 citation statements)

References 42 publications

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“…The damping due to surface scattering is added to the bulk damping in Equation ( 2) to obtain the corrected dielectric function for the shell material and is given by [43]:…”

Section: Methodsmentioning

confidence: 99%

“…Thus, the complex dielectric function of gold

is introduced by using the Drude–Lorentz model as follows [ 41 ]:

where

is the bulk dielectric function for gold [ 42 ], and

, and

are the plasma frequency, bulk damping, and damping due to surface scattering, respectively [ 41 ]. The damping due to surface scattering is added to the bulk damping in Equation (2) to obtain the corrected dielectric function for the shell material and is given by [ 43 ]:

…”

Section: Methodsmentioning

confidence: 99%

See 1 more Smart Citation

Numerical Study on the Surface Plasmon Resonance Tunability of Spherical and Non-Spherical Core-Shell Dimer Nanostructures

Fernandes

Kang

2021

Nanomaterials

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The near-field enhancement and localized surface plasmon resonance (LSPR) on the core-shell noble metal nanostructure surfaces are widely studied for various biomedical applications. However, the study of the optical properties of new plasmonic non-spherical nanostructures is less explored. This numerical study quantifies the optical properties of spherical and non-spherical (prolate and oblate) dimer nanostructures by introducing finite element modelling in COMSOL Multiphysics. The surface plasmon resonance peaks of gold nanostructures should be understood and controlled for use in biological applications such as photothermal therapy and drug delivery. In this study, we find that non-spherical prolate and oblate gold dimers give excellent tunability in a wide range of biological windows. The electromagnetic field enhancement and surface plasmon resonance peak can be tuned by varying the aspect ratio of non-spherical nanostructures, the refractive index of the surrounding medium, shell thickness, and the distance of separation between nanostructures. The absorption spectra exhibit considerably greater dependency on the aspect ratio and refractive index than the shell thickness and separation distance. These results may be essential for applying the spherical and non-spherical nanostructures to various absorption-based applications.

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“…The damping due to surface scattering is added to the bulk damping in Equation ( 2) to obtain the corrected dielectric function for the shell material and is given by [43]:…”

Section: Methodsmentioning

confidence: 99%

“…Thus, the complex dielectric function of gold

is introduced by using the Drude–Lorentz model as follows [ 41 ]:

where

is the bulk dielectric function for gold [ 42 ], and

, and

…”

Section: Methodsmentioning

confidence: 99%

Numerical Study on the Surface Plasmon Resonance Tunability of Spherical and Non-Spherical Core-Shell Dimer Nanostructures

Fernandes

Kang

2021

Nanomaterials

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show abstract

“…19 . However, it should be pointed out that direct usage of Ag's dielectric constants from reference is not appropriate, as this omits effect of surface dispersion of conduction electrons which increases light absorption and deceases light scattering 20,21 , and this effect is numerically demonstrated later in the section: "Spheroidal nanoparticles".…”

Section: Silica/agmentioning

confidence: 99%

Toward transparent projection display: recent progress in frequency-selective scattering of RGB light based on metallic nanoparticle’s localized surface plasmon resonance

Ye¹,

Liu²,

Chen³

2019

Opto-Electronic Advances

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A transparent display simultaneously enables visualization of the images displayed on it as well as the view behind it, and therefore can be applied to, for instance, augmented reality (AR), virtual reality (VR), and head up display (HUD). Many solutions have been proposed for this purpose. Recently, the idea of frequency-selective scattering of red, green and blue light while transmitting visible light of other colours to achieve transparent projection display has been proposed, by taking advantage of metallic nanoparticle's localized surface plasmon resonance (LSPR). In this article, a review of the recent progress of frequency-selective scattering of red, green and blue light that are based on metallic nanoparticle's LSPR is presented. A discussion of method for choosing appropriate metal(s) is first given, followed by the definition of a figure of merit used to quantify the performance of a designed nanoparticle structure. Selective scattering of various nanostructures, including sphere-shaped nanoparticles, ellipsoidal nanoparticles, super-sphere core-shell nanoparticles, metallic nanocubes, and metallic nanoparticles combined with gain materials, are discussed in detail. Each nanostructure has its own advantages and disadvantages, but the combination of the metallic nanoparticle with gain materials is a more promising way since it has the potential to generate ultra-sharp scattering peaks (i.e., high frequency-selectivity).Ye Y Y, Liu Z, Chen T P. Toward transparent projection display: recent progress in frequency-selective scattering of RGB light based on metallic nanoparticle's localized surface plasmon resonance. Opto-Electron Adv 2, 190020 (2019).

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“…For the calculated efficiencies shown in Figures 2, 3 and 4, Mie's theory takes the following parameters as its inputs: the surrounding medium's dielectric function = 2 = 2.25 , optimized nanostructure's dimensions (i.e., core diameter and shell thickness for a core-shell structure, or diameter for a nanosphere), metal's sizedependent dielectric function given by equation (2), silica's dielectric function for the core-shell structure (for a structure without gain material, = 2 = 2.1025; for a structure with gain material = 2 = (1.45 + ) 2 , where = 1.45 + is from equation (6) and the optimized is constant over the whole spectrum).…”

Section: Resultsmentioning

confidence: 99%

Sharp selective scattering of red, green, and blue light achieved via gain material’s loss compensation

Ye¹,

Liu²,

Song³

et al. 2019

Opt. Express

Self Cite

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For a transparent projection screen based on metallic nanoparticle's localized surface plasmon resonance (LSPR), in the ideal case the metallic nanoparticles dispersed in a transparent matrix only selectively scatter red, green and blue light and transmit the visible light of other colours. However, metal's optical loss and size effect at nanoscale degenerate the desired performance by broadening the resonance peak width and increasing the absorption ratio. In this work, it is shown that the problem can be solved by introducing gain material. Numerical simulations are performed on nanostructures based on silver (Ag), gold (Au) or aluminium (Al) with or without gain material, to examine the effect of gain material and to search for suitable structures for sharp selective scattering of red, green and blue light. And it is found that introducing gain material greatly improves performance of the structures based on Ag or Au except the structures based on Al. The most suitable structures for sharp selective scattering of red, green and blue light are respectively found to be the core-shell structures of silica@Au, silica@Ag and Ag@silica, all with gain material.

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Effect of Surface Scattering of Electrons on Ratios of Optical Absorption and Scattering to Extinction of Gold Nanoshell

Cited by 15 publications

References 42 publications

Numerical Study on the Surface Plasmon Resonance Tunability of Spherical and Non-Spherical Core-Shell Dimer Nanostructures

Numerical Study on the Surface Plasmon Resonance Tunability of Spherical and Non-Spherical Core-Shell Dimer Nanostructures

Toward transparent projection display: recent progress in frequency-selective scattering of RGB light based on metallic nanoparticle’s localized surface plasmon resonance

Sharp selective scattering of red, green, and blue light achieved via gain material’s loss compensation

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