Exploiting the interaction between a semiconductor nanosphere and a thin metal film for nanoscale plasmonic devices

Li, H.; Xu, Yi; Xiang, Jin; Li, X. F.; Zhang, C. Y.; Tie, Shaolong; Lan, Sheng

doi:10.1039/c6nr06504j

Cited by 30 publications

(38 citation statements)

References 41 publications

(65 reference statements)

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“…It is noticed that the MD moment contributes negatively to the total extinction in the presence of the Ag film, because of bianisotropic effect implying a destructive interference between the fields scattered by the ED and MD moments [36]. More importantly, such bianisotropic effect also results in the shrinkage of the ED resonance's line width [14], as clearly shown in Figure 1C.…”

Section: Resultsmentioning

confidence: 86%

“…Similarly, the hybrid concept was used to boost the Purcell factor and generate efficient hot electron luminescence from a silicon (Si) nanowire coated with a thin Ag film [12]. Furthermore, such a strategy can be generalized to the three-dimensional case for realizing strong localization of optical field in particleon-film systems where dielectric nanoparticles (such as Si nanospheres) supporting distinct Mie resonances were used [13,14]. As an exemplary application, the significantly enhanced electric field mediated by the mirrorimage-induced magnetic dipole mode was exploited to enhance Raman scattering and photoluminescence [15].…”

Section: Introductionmentioning

confidence: 99%

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Tailoring the spatial localization of bound state in the continuum in plasmonic-dielectric hybrid system

Xiang

Chen

et al. 2020

Nanophotonics

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Bound states in the continuum (BIC) are considered as an effective means to dramatically elongate the trapping time of light. However, light-matter interaction depends not only on the life-time of an optical mode, but also on its mode volume. Therefore, increasing the lifetime of an optical mode and minimizing the mode volume simultaneously, utilizing the BIC resembles a promising way for enhancing light-matter interaction. Herein, we have proposed a novel hybrid plasmonic-dielectric structure to manipulate the mode volume of BIC. For the Friedrich-Wintgen BIC, the electric field is strongly confined in the dielectric nanoparticle, leading to the considerable field enhancement compared with the single dielectric nanoparticle case. In contrast, strong localization of electric field can be achieved along the surface normal direction for the symmetry-protected BIC, leading to one order of magnitude reduction of mode volume in one unit cell compared with the conventional symmetry-protected BIC of all-dielectric structure. The proposed hybrid photonic system could provide an ideal flat platform for advanced manipulation of light-matter interaction.

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Section: Resultsmentioning

confidence: 86%

Section: Introductionmentioning

confidence: 99%

Tailoring the spatial localization of bound state in the continuum in plasmonic-dielectric hybrid system

Xiang

Chen

et al. 2020

Nanophotonics

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“…As some examples, we will show in the following numerical simulation the possible applications of the sharp MD resonance in nanoscale sensing and color display. For practical applications, the metal substrate is chosen to be a 50- nm-thick Au film, which has been used in our previous study [28]. The physical mechanism for the line width compression of the magnetic dipole resonance is the coherent interaction of the magnetic dipole and its mirror image induced by the metal substrate.…”

Section: Practical Applicationsmentioning

confidence: 99%

“…Previously, it has been demonstrated that intensity shift sensors based on Si NS dimers possess much higher sensitivity than wavelength shift sensors based on plasmonic nanoparticles/nanostructures [51]. In addition, the sensitivity of the Si NS placed on a metal substrate and excited by linearly polarized light was also experimentally studied in our previous work [28]. In our case, the scattering spectrum dominated by a sharp MD resonance with a narrow line width is quite suitable for sensing applications, as demonstrated in the following.…”

Section: Practical Applicationsmentioning

confidence: 99%

Metal Substrate-Induced Line Width Compression in the Magnetic Dipole Resonance of a Silicon Nanosphere Illuminated by a Focused Azimuthally Polarized Beam

2018

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We investigate the modification of the magnetic dipole resonance of a silicon nanosphere, which is illuminated by a focused azimuthally polarized beam, induced by a metal substrate. It is found that the magnetic dipole of the silicon nanosphere excited by the focused azimuthally polarized beam and its image dipole induced by the metal substrate are out of phase. The interference of these two anti-parallel dipoles leads to a dramatic line width compression in the magnetic dipole resonance, manifested directly in the scattering spectrum of the silicon nanosphere. The quality factor of the modified magnetic dipole resonance is enhanced by a factor of ∼ 2.5 from ∼ 14.62 to ∼ 37.25 as compared with that of the silicon nanosphere in free space. Our findings are helpful for understanding the mode hybridization in the silicon nanosphere placed on a metal substrate and illuminated by a focused azimuthally polarized beam and useful for designing photonic functional devices such as nanoscale sensors and color displayers.

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“…In principle, the scattering properties of the Si NS can be modified by varying either the surrounding environment or the illumination configuration . It has been shown that both the forward and backward scattering spectra of a Si NS can be changed by using a metal film . Moreover, it has been demonstrated that optical pulling force acting on a nanoparticle can be generated by using a single Bessel beam or two interfering plane waves which modify the forward and backward scattering properties of the nanoparticle .…”

Section: Introductionmentioning

confidence: 99%

Manipulating the Orientations of the Electric and Magnetic Dipoles Induced in Silicon Nanoparticles for Multicolor Display

Xiang

Zhou

et al. 2018

Laser & Photonics Reviews

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Artificial control of colors based on plasmonic and dielectric nanostructures is not only interesting for fundamental research, but also important for practical applications. Apart from spatial resolution, chromaticity, angular independence, and dynamical color-tuning have emerged as the most desirable functions for structural color. Here, it is shown theoretically that the orientations of the electric or magnetic dipoles induced in a silicon nanoparticle can be manipulated by using an evanescent wave excited by sor p-polarized light, and it is experimentally demonstrated that the scattering light color can be controlled by simply varying the polarization of the illumination light. It is revealed that the excitation of a silicon nanoparticle using an evanescent wave is equivalent to that of using both the incident and reflected light, enabling the manipulation of the scattering light color by controlling the orientations of the electric and magnetic dipoles. In addition, an enhanced scattering light intensity and a completely dark background are achieved by using evanescent wave excitation. More importantly, a color-tuning display with a spatial resolution close to the optical diffraction limit, and a good chromaticity on an array of silicon nanopillars fabricated on a silica substrate is demonstrated, which are compatible with the current fabrication technology of silicon chips.

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Exploiting the interaction between a semiconductor nanosphere and a thin metal film for nanoscale plasmonic devices

Cited by 30 publications

References 41 publications

Tailoring the spatial localization of bound state in the continuum in plasmonic-dielectric hybrid system

Tailoring the spatial localization of bound state in the continuum in plasmonic-dielectric hybrid system

Metal Substrate-Induced Line Width Compression in the Magnetic Dipole Resonance of a Silicon Nanosphere Illuminated by a Focused Azimuthally Polarized Beam

Manipulating the Orientations of the Electric and Magnetic Dipoles Induced in Silicon Nanoparticles for Multicolor Display

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