Haiyang Ren scite author profile

Haiyang Ren

3Publications

23Citation Statements Received

20Citation Statements Given

How they've been cited

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130

Affiliations

Institute of Semiconductors, Shandong Normal University, Wuhan University of Technology

Publications

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LSPR optical fiber biosensor based on a 3D composite structure of gold nanoparticles and multilayer graphene films

et al. 2020

Opt. Express

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In this paper, a localized surface-plasmon resonance (LSPR) biosensor, which uses a U-shaped multi-mode fiber (U-MMF), is introduced and investigated. It is modified with a complex of three-dimensional (3D) gold nanoparticles and multilayer graphene as spacer: n*(Au/G)@U-MMF, where n denotes the layer number of gold nanoparticles. The gold nanoparticles were synthesized by reducing chloroauric acid. Graphene films were formed using a liquid/chemical method. The number of gold-nanoparticle layers was found to be critical for the performance of the sensor. Moreover, using the ﬁnite-difference time domain, 3D nanostructures, with a wide range of gold-nanoparticle layers, were explored. The sensor showed the sensitivity of 1251.44 nm/RIU, as well as high stability and repeatability; for the measurement-process of time- and concentration-dependent DNA hybridization kinetics with detection concentrations, ranging from 0.1nM to 100 nM, the sensor displayed excellent performance, which points towards a vast potential in the field of medical diagnostics.

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Compact Design of Annular-Microstrip-Fed mmW Antenna Arrays

Lin

Wang³

et al. 2021

Sensors

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In this paper, a series of four novel microstrip antenna array designs based on different annular-microstrip feeding lines at 60-GHz millimeter wave (mmW) band are proposed, aiming at the potential usage of the mmW coverage antenna with multi-directional property. As the feeding network, the annular contour microstrip lines are employed to connect the patch units so as to form a more compact array. Our first design is to use an outer contour annular microstrip line to connect four-direction linear arrays composed of 1 × 3 rectangular patches, thus the gain of 8.4 dBi and bandwidth of over 300 MHz are obtained. Our second design is to apply the two-direction pitchfork-shaped array each made up of two same linear arrays as the above, therefore the gain of 9.65 dBi and bandwidth of around 250 MHz are achieved. Our third design is to employ dual (inner and outer contour) annular-microstrip feeding lines to interconnect the above four-direction linear arrays, while our fourth design is to bring bridged annular-microstrip feeding lines, both of which can realize the goal of multi-directional radiation characteristic and higher gain of over 10 dBi.

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Broadband terahertz wavefront modulation based on flexible metasurface

Ren

Yue

Liu

et al. 2022

Optics Communications

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Haiyang Ren

LSPR optical fiber biosensor based on a 3D composite structure of gold nanoparticles and multilayer graphene films

Compact Design of Annular-Microstrip-Fed mmW Antenna Arrays

Broadband terahertz wavefront modulation based on flexible metasurface

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