Zhiping Yin scite author profile

In this paper, a liquid crystal (LC) based tunable metamaterial absorber with dual-band absorption is presented. The proposed absorber is analysed both numerically and experimentally. The analysis shows that the two absorption peaks, originating from the new resonant structure, are experimentally detected at 269.8 GHz and 301.4 GHz when no bias voltage is applied to the LC layer. In order to understand the absorption mechanisms, simulation results for the surface current and power loss distributions are presented. Since liquid crystals are used as the dielectric layer to realize the electrically tunable absorber, a frequency tunability of 2.45% and 3.65% for the two absorption peaks is experimentally demonstrated by changing the bias voltage of the LC layer from 0 V to 12 V. Furthermore, the absorber is polarization independent and a high absorption for a wide range of oblique incidence is achieved. The designed absorber provides a way forward for the realization of tunable metamaterial devices that can be applied in multi-band detection and imaging.

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Outliers-Robust CFAR Detector of Gaussian Clutter Based on the Truncated-Maximum-Likelihood- Estimator in SAR Imagery

Luo

Yang

et al. 2020

IEEE Trans. Intell. Transport. Syst.

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Actively controllable terahertz switches with graphene-based nongroove gratings

Luo

Wang

et al. 2017

Photon. Res.

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High-Efficiency Visible Transmitting Polarizations Devices Based on the GaN Metasurface

Guo

et al. 2018

Nanomaterials

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Metasurfaces are capable of tailoring the amplitude, phase, and polarization of incident light to design various polarization devices. Here, we propose a metasurface based on the novel dielectric material gallium nitride (GaN) to realize high-efficiency modulation for both of the orthogonal linear polarizations simultaneously in the visible range. Both modulated transmitted phases of the orthogonal linear polarizations can almost span the whole 2π range by tailoring geometric sizes of the GaN nanobricks, while maintaining high values of transmission (almost all over 90%). At the wavelength of 530 nm, we designed and realized the beam splitter and the focusing lenses successfully. To further prove that our proposed method is suitable for arbitrary orthogonal linear polarization, we also designed a three-dimensional (3D) metalens that can simultaneously focus the X-, Y-, 45°, and 135° linear polarizations on spatially symmetric positions, which can be applied to the linear polarization measurement. Our work provides a possible method to achieve high-efficiency multifunctional optical devices in visible light by extending the modulating dimensions.

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Electrically tunable liquid crystal terahertz device based on double-layer plasmonic metamaterial

et al. 2019

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Tunable manipulation of terahertz wavefront based on graphene metasurfaces

Luo

Wang

Guo

et al. 2017

J. Opt.

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We have systematically investigated the performances of a tunable graphene metasurface that can dynamically manipulate the terahertz wavefronts. The metasurface consists of a silver substrate, SiO2 interlayer and the top graphene ribbons that can exhibit plasmon resonances to realize a phase shift by changing the Fermi levels of graphene ribbons. The plasmon resonances in graphene ribbons and Fabry–Perot resonances in the SiO2 interlayer work together for making the designed metasurface cover 2π phase range nearly. In the simulations, we can realize anomalous reflection at any angle by using the continuous phase modulation. On this basis, a reflective focusing lens based on the graphene metasurface has also been designed, which is designed in the frequency of 5.0 THz with a reasonable operation bandwidth from 4.5 THz to 6.5 THz. The corresponding focal lengths are designed as 300 μm and 100 μm, and the depths of focus (full width at half maximum along the Z direction) are 114 μm and 104 μm, respectively. Especially, the diameters of focal points (full width at half maximum along the X direction) are 29.5 μm and 24.1 μm, which are smaller than a half-wavelength (30 μm) in the focusing plane. It indicates that our designed focusing lenses have superior performance and can provide an opportunity to develop a tunable wavefront-controlling device.

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Heat dissipation performance of silicon solar cells by direct dielectric liquid immersion under intensified illuminations

et al. 2011

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High-efficiency dielectric metasurfaces for simultaneously engineering polarization and wavefront

et al. 2018

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Zhiping Yin

Electrically tunable terahertz dual-band metamaterial absorber based on a liquid crystal

Outliers-Robust CFAR Detector of Gaussian Clutter Based on the Truncated-Maximum-Likelihood- Estimator in SAR Imagery

Actively controllable terahertz switches with graphene-based nongroove gratings

High-Efficiency Visible Transmitting Polarizations Devices Based on the GaN Metasurface

Electrically tunable liquid crystal terahertz device based on double-layer plasmonic metamaterial

Tunable manipulation of terahertz wavefront based on graphene metasurfaces

Heat dissipation performance of silicon solar cells by direct dielectric liquid immersion under intensified illuminations

High-efficiency dielectric metasurfaces for simultaneously engineering polarization and wavefront

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