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Giant photothermal nonlinearity in a single silicon nanostructure

Author

Listed:
  • Yi-Shiou Duh

    (National Taiwan University)

  • Yusuke Nagasaki

    (Osaka University)

  • Yu-Lung Tang

    (National Taiwan University)

  • Pang-Han Wu

    (National Taiwan University)

  • Hao-Yu Cheng

    (Institute of Physics, Academia Sinica)

  • Te-Hsin Yen

    (National Taiwan University)

  • Hou-Xian Ding

    (National Taiwan University)

  • Kentaro Nishida

    (Osaka University
    AIST-Osaka University Advanced Photonics and Biosensing Open Innovation Laboratory, AIST)

  • Ikuto Hotta

    (Osaka University)

  • Jhen-Hong Yang

    (Institute of Photonic System, National Chiao Tung University)

  • Yu-Ping Lo

    (Institute of Imaging and Biomedical Photonics, National Chiao Tung University)

  • Kuo-Ping Chen

    (Institute of Imaging and Biomedical Photonics, National Chiao Tung University)

  • Katsumasa Fujita

    (Osaka University
    AIST-Osaka University Advanced Photonics and Biosensing Open Innovation Laboratory, AIST)

  • Chih-Wei Chang

    (National Taiwan University)

  • Kung-Hsuan Lin

    (Institute of Physics, Academia Sinica)

  • Junichi Takahara

    (Osaka University
    Osaka University)

  • Shi-Wei Chu

    (National Taiwan University
    National Taiwan University
    Brain Research Center, National Tsing Hua University)

Abstract

Silicon photonics have attracted significant interest because of their potential in integrated photonics components and all-dielectric meta-optics elements. One major challenge is to achieve active control via strong photon–photon interactions, i.e. optical nonlinearity, which is intrinsically weak in silicon. To boost the nonlinear response, practical applications rely on resonant structures such as microring resonators or photonic crystals. Nevertheless, their typical footprints are larger than 10 μm. Here, we show that 100 nm silicon nano-resonators exhibit a giant photothermal nonlinearity, yielding 90% reversible and repeatable modulation from linear scattering response at low excitation intensities. The equivalent nonlinear index is five-orders larger compared with bulk, based on Mie resonance enhanced absorption and high-efficiency heating in thermally isolated nanostructures. Furthermore, the nanoscale thermal relaxation time reaches nanosecond. This large and fast nonlinearity leads to potential applications for GHz all-optical control at the nanoscale and super-resolution imaging of silicon.

Suggested Citation

  • Yi-Shiou Duh & Yusuke Nagasaki & Yu-Lung Tang & Pang-Han Wu & Hao-Yu Cheng & Te-Hsin Yen & Hou-Xian Ding & Kentaro Nishida & Ikuto Hotta & Jhen-Hong Yang & Yu-Ping Lo & Kuo-Ping Chen & Katsumasa Fujit, 2020. "Giant photothermal nonlinearity in a single silicon nanostructure," Nature Communications, Nature, vol. 11(1), pages 1-9, December.
    • Handle: RePEc:nat:natcom:v:11:y:2020:i:1:d:10.1038_s41467-020-17846-6
    DOI: 10.1038/s41467-020-17846-6
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    Cited by:

    1. Yu-Lung Tang & Te-Hsin Yen & Kentaro Nishida & Chien-Hsuan Li & Yu-Chieh Chen & Tianyue Zhang & Chi-Kang Pai & Kuo-Ping Chen & Xiangping Li & Junichi Takahara & Shi-Wei Chu, 2023. "Multipole engineering by displacement resonance: a new degree of freedom of Mie resonance," Nature Communications, Nature, vol. 14(1), pages 1-8, December.
    2. Tingting Wu & Chongwu Wang & Guangwei Hu & Zhixun Wang & Jiaxin Zhao & Zhe Wang & Ksenia Chaykun & Lin Liu & Mengxiao Chen & Dong Li & Song Zhu & Qihua Xiong & Zexiang Shen & Huajian Gao & Francisco J, 2024. "Ultrastrong exciton-plasmon couplings in WS2 multilayers synthesized with a random multi-singular metasurface at room temperature," Nature Communications, Nature, vol. 15(1), pages 1-9, December.

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