\begin{document}${\left( {\lambda /n} \right)^2}/640$\end{document} which is over 300 times smaller than that of the input silicon waveguide. When the middle slot silicon waveguide width WSi = 120 nm, the insertion loss reaches a minimum value of 2.8 dB. In our design, we adopt the design of silicon-based hybrid plasmonic waveguides. In this design, a layer of material with low refractive index is inserted between the metal layer and the silicon layer to act as a “container” of light field, which makes this silicon-based hybrid plasmonic waveguides have less loss than the traditional metal plasmonic waveguides, and can still maintain high optical field localization. Such silicon-based hybrid surface plasmon nanofocusing devices with simple structures and excellent performances are promising alternatives for future applications in optical field manipulation, optical sensing, nonlinear optical devices, and optical phase-change storage."> Experimental research on ultracompact silicon hybrid plasmonic nanofocusing device - 必威体育下载

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    Sun Peng-Fei, Zhu Ke-Jian, Xu Peng-Fei, Liu Xing-Peng, Sun Tang-You, Li Hai-Ou, Zhou Zhi-Ping
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    • Abstract views:2984
    • PDF Downloads:70
    • Cited By:0
    Publishing process
    • Received Date:18 December 2021
    • Accepted Date:01 June 2022
    • Available Online:15 September 2022
    • Published Online:05 October 2022

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