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    Journals >Infrared and Laser Engineering >Volume 49 >Issue 12 >Page 20201059 > Article
    • Infrared and Laser Engineering
    • Vol. 49, Issue 12, 20201059 (2020)
    Terahertz flexible stretchable metasurface based on double resonance response (Invited)
    Jing Wang and Hao Tian*
    Author Affiliations
  • Key Laboratory of Micro-Nano Optoelectronic Information System, Ministry of Industry and Information Technology, School of Physics, Harbin Institute of Technology, Harbin 150001, China
    • show less
    DOI: 10.3788/IRLA20201059 Cite this Article
    Jing Wang, Hao Tian. Terahertz flexible stretchable metasurface based on double resonance response (Invited)[J]. Infrared and Laser Engineering, 2020, 49(12): 20201059 Copy Citation Text show less
    References

    [1] P U Jepsen, D G Cooke, M Koch. Terahertz spectroscopy and imaging-Modern techniques and applications. Laser & Photonics Reviews, 5, 1-43(2011).

    [2] M Hangyo. Development and future prospects of terahertz technology. Japanese Journal of Applied Physics, 54, 120101(2015).

    [3] W Chan, J Deibel, D Mittleman. Imaging with terahertz radiation. Reports on Progress in Physics, 70, 1325-1379(2007).

    [4] H Ji, B Zhang, G Wang. Photo-excited multi-frequency terahertz switch based on a composite metamaterial structure. Optics Communications, 412, 37-40(2018).

    [5] X Liu, K Fan, I V Shadrivov. Experimental realization of a terahertz all-dielectric metasurface absorber. Optics Express, 25, 191-210(2017).

    [6] W J Padilla, A J Taylor, C Highstrete. Dynamical electric and magnetic metamaterial response at terahertz frequencies. Physical Review Letters, 96, 107401(2006).

    [7] X Zhao, J Schalch, J Zhang. Electromechanically tunable metasurface transmission waveplate at terahertz frequencies. Optica, 5, 303-310(2018).

    [8] W J Padilla, D N Basov, D R Smith. Negative refractive index metamaterials. Materials Today, 9, 28-35(2006).

    [9] D Schurig, J J Mock, B J Justice. Metamaterial electromagnetic cloak at microwave frequencies. Science, 314, 977-980(2006).

    [10] A Lagarkov, V Kissel. Near-perfect imaging in a focusing system based on a left-handed-material plate. Physical Review Letters, 92, 077401(2004).

    [11] S Liu, H Chen, T J Cui. A broadband terahertz absorber using multi-layer stacked bars. Applied Physics Letters, 106, 151601(2015).

    [12] J Lv, R Y Yuan, X Song. Broadband polarization-insensitive terahertz absorber based on heavily doped silicon surface relief structures. Journal of Applied Physics, 117, 013101(2015).

    [13] J Wang, H Tian, S Li. Efficient terahertz polarization conversion with hybrid coupling of chiral metamaterial. Optics Letters, 45, 1276-1279(2020).

    [14] N K Grady, J E Heyes, Roy C Dibakar. Terahertz metamaterials for linear polarization conversion and anomalous refraction. Science, 340, 1304-1307(2013).

    [15] L Stephen, N Yogesh, V Subramanian. Broadband asymmetric transmission of linearly polarized electromagnetic waves based on chiral metamaterial. Journal of Applied Physics, 123, 033103(2018).

    [16] S Walia, C M Shah, P Gutruf. Flexible metasurfaces and metamaterials: A review of materials and fabrication processes at micro- and nano-scales. Applied Physics Reviews, 2, 011303(2015).

    [17] F Zhang, S Feng, K Qiu. Mechanically stretchable and tunable metamaterial absorber. Applied Physics Letters, 106, 207402(2015).

    [18] H S Ee, R Agarwal. Tunable metasurface and flat optical zoom lens on a stretchable substrate. Nano Letters, 16, 2818-2823(2016).

    [19] R Kim, K Chung, J Y Kim. Metal nanoparticle array as a tunable refractive index material over broad visible and infrared wavelengths. ACS Photonics, 5, 1188-1195(2018).

    [20] W Peng, H Wu. Flexible and stretchable photonic sensors based on modulation of light transmission. Advanced Optical Materials, 7, 1900329(2019).

    [21] Z Xu, Y S Lin. A stretchable terahertz parabolic-shaped metamaterial. Advanced Optical Materials, 7, 1900379(2019).

    [22] D Morits, M Morits, V Ovchinnikov. Multifunctional stretchable metasurface for the THz range. Journal of Optics, 16, 032001(2014).

    [23] N Liu, H Giessen. Coupling effects in optical metamaterials. Angewandte Chemie International Edition, 49, 9838-9852(2010).

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