Spaser based on Fano resonance in a rod and concentric square ring-disk nanostructure

Huo, Yanyan; Jia, Tianqing; Zhang, Y.; Zhao, Hua; Zhang, S. A.; Feng, Donghai; Sun, Zhenrong

doi:10.1063/1.4868867

Cited by 31 publications

(19 citation statements)

References 29 publications

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“…This phenomenon is characterized by an asymmetrical scattering versus energy (or frequency) behavior. The high quality factor Q and spectral contrast of Fano resonances make them ideally suited for use in many applications where steep dispersions are essential, such as in slow light, biosensors, filters, surface enhanced Raman scattering, and surface plasmon lasers …”

Section: Introductionmentioning

confidence: 99%

Thermally tunable fano resonance of a conductive rubber‐based metamaterial

Qiu

Liu

2017

Micro & Optical Tech Letters

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Section: Introductionmentioning

confidence: 99%

Thermally tunable fano resonance of a conductive rubber‐based metamaterial

Qiu

Liu

2017

Micro & Optical Tech Letters

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“…In searching for new structures with simple geometries to support strong plasmon resonances and their constructive and destructive interference, newly, some new structures have been proposed to boost and enhance the energy of dark plasmon resonant modes that can be utilized in producing strong hotspots. Fractal nanoparticles in different Cayley tree orientation [18] and four-sided squares with a broken side [19] are the most recent examples of these nanostructures that were tailored to support strong Fano resonances at the optical frequencies. Although these irregular structures reflect remarkable optical responses, the plasmon response of spherical nanostructures are more promising and reliable for practical purposes.…”

Section: Introductionmentioning

confidence: 99%

A molecular plasmonic Fano-router: Using hotspots in a single-stone ring-like structure

Ahmadivand

Raju

Kaya

et al. 2016

Optics Communications

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In the past decade there has been outstanding, continuing interest in developing novel structures to engineer and control light-matter interactions in subwavelength dimensions with desired optical characteristics. Herein, we propose a unique plasmonic configuration consisting of a split-ring and a nanosphere in the split section (resembles a single-stone ring). We show that this simple and antisymmetric structure is able to support pronounced antisymmetric Fano resonance at the near-infrared region, while strong hotspots form at the gap space between the split-ring terminals and the nanosphere.The antisymmetric feature of the structure facilitates strong-dependency on the polarization of the incident beam. Having strong sensitivity to the incident polarization angle, we tailored a fast plasmonic Fano-router based on the behavior of Fano resonant mode. This study could help realizing Fano resonance based photonic devices using simple and antisymmetric nanostructures.

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“…A Fano resonance-based SPASER was found in a rod and concentric square ring-disk nanostructure. 28 We also proposed a dual-frequency SPASER based on the gainassisted metallic nanomatryushkas. 29 However, the SPASER properties in metal nanotubes were seldom reported, especially in their dimers.…”

mentioning

confidence: 99%

Efficient surface plasmon amplification in gain-assisted silver nanotubes and associated dimers

Jiang

2015

Journal of Applied Physics

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SPASER (surface plasmon amplification by stimulated emission of radiation) properties in active SiO2–Ag nanotubes and associated dimers have been investigated by using the scattering theory and the finite element method. In the active Ag nanotube, as the gain coefficient of the core increases to a critical value, a super-resonance occurs. The SPASER phenomenon also can be found in the active Ag nanotube dimer. The strong couplings between two nanotubes lead to larger gain threshold for the active Ag nanotube dimer compared with the active Ag nanotube. At the super-resonance, the maximal surface enhanced Raman scattering factor at the “hot spot” in the active Ag nanotube dimer can achieve about 8 × 1018, which is large enough for single molecule detection. Furthermore, with increasing the separation between two Ag nanotubes, the gain threshold value for the super-resonance of the active Ag nanotube dimer decreases, while the corresponding super-resonance wavelength increases first and then decreases.

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Spaser based on Fano resonance in a rod and concentric square ring-disk nanostructure

Cited by 31 publications

References 29 publications

Thermally tunable fano resonance of a conductive rubber‐based metamaterial

Thermally tunable fano resonance of a conductive rubber‐based metamaterial

A molecular plasmonic Fano-router: Using hotspots in a single-stone ring-like structure

Efficient surface plasmon amplification in gain-assisted silver nanotubes and associated dimers

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