Surface-plasmon-enhanced transmission through metallic film perforated with fractal-featured aperture array

Bao, Yongjun; Zhang, Bo; Wu, Zhe; Si, Jian-Wen; Wang, Mu; Peng, Ru‐Wen; Lu, Wu; Shao, Jianda; Li, Zhifeng; Hao, Xi-Ping; Ming, Nai‐Ben

doi:10.1063/1.2750528

Cited by 47 publications

(32 citation statements)

References 31 publications

(26 reference statements)

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“…It is found that the enhanced optical transmission through periodic metal hole arrays originates from the resonance of surface Plasmon mode, which is a surface wave generated by the interaction between the surface charge oscillation and the electromagnetic field of the light. The enhancement also depends on the array geometry (diameter, periodicity, and thickness of the metal film), light wavelength, angle of incidence, as well as material of a film [6][7][8][9][10]. For periodic slit arrays, Porto et al [11], who base their arguments on the transfer matrix formalism claim that surface plasmon excitation enhances the efficiency.…”

Section: Introductionmentioning

confidence: 96%

The extraordinary optical transmission through double-layer gold slit arrays

Xie¹,

Li²,

Fu³

et al. 2010

Optics Communications

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Section: Introductionmentioning

confidence: 96%

The extraordinary optical transmission through double-layer gold slit arrays

Xie¹,

Li²,

Fu³

et al. 2010

Optics Communications

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“…[9][10] These fantastic properties facilitate potential applications in extraordinary optical transmission, [11][12][13][14][15] microscopy, 16 and antennas, 17 etc.. Among the massive researches in this rapidly developing area, one of the intensively studied subjects is chiral metamaterial, which offers an alternative approach to realize negative refractive index.…”

mentioning

confidence: 99%

Optically nonactive assorted helix array with interchangeable magnetic/electric resonance

Xiong

Chen

Wang

et al. 2011

Applied Physics Letters

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We report here the designing of optically-nonactive metamaterial by assembling metallic helices with different chirality. With linearly polarized incident light, pure electric or magnetic resonance can be selectively realized, which leads to negative permittivity or negative permeability accordingly. Further, we show that pure electric or magnetic resonance can be interchanged at the same frequency band by merely changing the polarization of incident light for 90 degrees. This design demonstrates a unique approach to construct metamaterial.

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“…9b and c. Recent visible near-field studies of quasi-periodic structures have revealed focus spots at a significant distance away from the surface (5 µm) with widths less than half the optical wavelength [132]. Fractal aperture patterns in metal films have been investigated for their ability to show resonances over a broader wavelength range due to their self-similar structure [133].…”

Section: Lattice Effectsmentioning

confidence: 99%

Resonant optical transmission through hole‐arrays in metal films: physics and applications

Gordon¹,

Brolo

Sinton

et al. 2010

Laser & Photonics Reviews

162

104

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Extraordinary optical transmission through an array of holes in a metal film was reported by Ebbesen and coworkers in 1998. Since that work there has been abundant research activity aimed at understanding the physics and at the development of the many applications associated with this phenomenon, hence the topic of this review. The study of hole-arrays in a metal is not new -theoretical contributions on a small-hole array date back to Lord Rayleigh's description of Wood's anomaly in 1907 and there has been considerable research on metal meshes and holearrays since 1962. Bethe's theory, adapted to treat hole-arrays, is the simplest theoretical description of the transmission resonance. Following a description of this basic theory, we present the research on the additional effects from variations in real metal properties at different wavelengths, film thickness, holeshape and lattice configuration. The many promising applications being developed using hole-arrays are examined, including polarization control, filtering, switching, nonlinear optics, surface plasmon resonance sensing, surface-enhanced fluorescence, surface-enhanced Raman scattering, absorption spectroscopy, and quantum interactions. Finally, the various approaches, developments in hole-array fabrication, and integration of hole-arrays into devices are described. (top left) Schematic of resonant transmission through nanohole array using scanning electron microscope image of as-fabricated sample. (top right) Microfluidic chip incorporating nanohole arrays. (bottom) Composite image of array of nanohole arrays used as sensors in a immunoassay-like microfluidic device, showing (left to right) schematic of microfluidic layout, microscope image of arrays in microfluidic channels, and laser transmission modified by adsorbed molecules.

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Surface-plasmon-enhanced transmission through metallic film perforated with fractal-featured aperture array

Cited by 47 publications

References 31 publications

The extraordinary optical transmission through double-layer gold slit arrays

The extraordinary optical transmission through double-layer gold slit arrays

Optically nonactive assorted helix array with interchangeable magnetic/electric resonance

Resonant optical transmission through hole‐arrays in metal films: physics and applications

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