Yingran He scite author profile

Electromagnetic absorbers have drawn increasing attention in many areas. A series of plasmonic and metamaterial structures can work as efficient narrowband absorbers due to the excitation of plasmonic or photonic resonances, providing a great potential for applications in designing selective thermal emitters, biosensing, etc. In other applications such as solar-energy harvesting and photonic detection, the bandwidth of light absorbers is required to be quite broad. Under such a background, a variety of mechanisms of broadband/multiband absorption have been proposed, such as mixing multiple resonances together, exciting phase resonances, slowing down light by anisotropic metamaterials, employing high loss materials and so on.

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Graphene nano-ribbon waveguides of record-small mode area and ultra-high effective refractive indices for future VLSI

He¹,

Zhang²,

He³

2013

Opt. Express

155

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Electronics circuits keep shrinking in dimensions, as requested by Moore's law. In contrast, photonic waveguides and circuit elements still have lateral dimensions on the order of the wavelength. A key to make photonics have a microelectronics-like development is a drastic reduction of size. To achieve this, we need a low-loss nanoscale waveguide with a drastically reduced mode area and an ultra-high effective refractive index. For this purpose, we propose here several low-loss waveguide structures based on graphene nano-ribbons. An extremely small mode area (~10(-7)λ(0)(2), one order smaller than the smallest mode area of any waveguide that has ever been reported in the literature; here λ(0) is the operating wavelength in vacuum) and an extremely large effective refractive index (several hundreds) are achieved. As a device example, a nano-ring cavity of ultra-small size (with a diameter of ~10(-2)λ(0)) is designed. Our study paves the way for future VLSI (very-large-scale integration) optoelectronics.

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A sensitive and reliable dopamine biosensor was developed based on the Au@carbon dots–chitosan composite film

Huang

Zhang

et al. 2014

Biosensors and Bioelectronics

197

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UiO-66 incorporated thin-film nanocomposite membranes for efficient selenium and arsenic removal

Tang

et al. 2017

Journal of Membrane Science

194

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Revealing the truth about ‘trapped rainbow’ storage of light in metamaterials

Jin

2012

Sci Rep

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It was claimed that the incident light can be gradually slowed down and finally trapped in a tapered metamaterial waveguide. Here we show that the energy incident from the input port of the tapered metamaterial waveguide will be totally reflected (instead of being trapped) due to the strong intermodal coupling between the forward and backward modes. The underlying physical mechanism for this strong intermodal-coupling is given. The occurrence of energy reflection is unambiguously proved using several independent methods, (1) the semi-analytical mode matching technique, (2) the numerical finite element simulation, (3) the requirement of energy and momentum conservation, and (4) an experimental verification at microwave frequency. The dream of ‘trapped rainbow’ for storage of light might still be possible if this intermodal coupling could be blocked, and our study provides a useful guidance for such an endeavor.

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Carbon dots and chitosan composite film based biosensor for the sensitive and selective determination of dopamine

Huang

Zhang

et al. 2013

Analyst

148

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A simple, sensitive and reliable dopamine (DA) biosensor was developed based on a carbon dots (CDs) and chitosan (CS) composite film modified glassy carbon electrode (CDs-CS/GCE). Under optimal conditions, the CDs-CS/GCE showed a better electrochemical response for the detection of DA than that of the glassy carbon electrode (GCE). The oxidation peak current (Ipa) of DA was linear with the concentration of DA in the range from 0.1 μM to 30.0 μM with the limit of detection as 11.2 nM (3S/N). The CDs-CS/GCE was applied to the detection of DA content in an injection solution of DA with satisfactory results.

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Optical field enhancement in nanoscale slot waveguides of hyperbolic metamaterials

Yang

2012

Opt. Lett.

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Nanoscale slot waveguides of hyperbolic metamaterials are proposed and demonstrated for achieving large optical field enhancement. The dependence of the enhanced electric field within the air slot on waveguide mode coupling and permittivity tensors of hyperbolic metamaterials is analyzed both numerically and analytically. Optical intensity in the metamaterial slot waveguide can be more than 25 times stronger than that in a conventional silicon slot waveguide, due to tight optical mode confinement enabled by the ultrahigh refractive indices supported in hyperbolic metamaterials. The electric field enhancement effects are also verified with the realistic metal-dielectric multilayer waveguide structure.

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Na+ functionalized carbon quantum dot incorporated thin-film nanocomposite membranes for selenium and arsenic removal

Zhao

Chung

2018

Journal of Membrane Science

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Yingran He

Plasmonic and metamaterial structures as electromagnetic absorbers

Graphene nano-ribbon waveguides of record-small mode area and ultra-high effective refractive indices for future VLSI

A sensitive and reliable dopamine biosensor was developed based on the Au@carbon dots–chitosan composite film

UiO-66 incorporated thin-film nanocomposite membranes for efficient selenium and arsenic removal

Revealing the truth about ‘trapped rainbow’ storage of light in metamaterials

Carbon dots and chitosan composite film based biosensor for the sensitive and selective determination of dopamine

Optical field enhancement in nanoscale slot waveguides of hyperbolic metamaterials

Na+ functionalized carbon quantum dot incorporated thin-film nanocomposite membranes for selenium and arsenic removal

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