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Highly efficient nonlinear optical emission from a subwavelength crystalline silicon cuboid mediated by supercavity mode

Author

Listed:
  • Mingcheng Panmai

    (South China Normal University)

  • Jin Xiang

    (South China Normal University)

  • Shulei Li

    (South China Normal University)

  • Xiaobing He

    (South China Normal University)

  • Yuhao Ren

    (Sun Yat-sen University)

  • Miaoxuan Zeng

    (Sun Yat-sen University)

  • Juncong She

    (Sun Yat-sen University)

  • Juntao Li

    (Sun Yat-sen University)

  • Sheng Lan

    (South China Normal University)

Abstract

The low quantum efficiency of silicon (Si) has been a long-standing challenge for scientists. Although improvement of quantum efficiency has been achieved in porous Si or Si quantum dots, highly efficient Si-based light sources prepared by using the current fabrication technooloy of Si chips are still being pursued. Here, we proposed a strategy, which exploits the intrinsic excitation of carriers at high temperatures, to modify the carrier dynamics in Si nanoparticles. We designed a Si/SiO2 cuboid supporting a quasi-bound state in the continuum (quasi-BIC) and demonstrated the injection of dense electron-hole plasma via two-photon-induced absorption by resonantly exciting the quasi-BIC with femtosecond laser pulses. We observed a significant improvement in quantum efficiency by six orders of magnitude to ~13%, which is manifested in the ultra-bright hot electron luminescence emitted from the Si/SiO2 cuboid. We revealed that femtosecond laser light with transverse electric polarization (i.e., the electric field perpendicular to the length of a Si/SiO2 cuboid) is more efficient for generating hot electron luminescence in Si/SiO2 cuboids as compared with that of transverse magnetic polarization (i.e., the magnetic field perpendicular to the length of a Si/SiO2 cuboid). Our findings pave the way for realizing on-chip nanoscale Si light sources for photonic integrated circuits and open a new avenue for manipulating the luminescence properties of semiconductors with indirect bandgaps.

Suggested Citation

  • Mingcheng Panmai & Jin Xiang & Shulei Li & Xiaobing He & Yuhao Ren & Miaoxuan Zeng & Juncong She & Juntao Li & Sheng Lan, 2022. "Highly efficient nonlinear optical emission from a subwavelength crystalline silicon cuboid mediated by supercavity mode," Nature Communications, Nature, vol. 13(1), pages 1-9, December.
    • Handle: RePEc:nat:natcom:v:13:y:2022:i:1:d:10.1038_s41467-022-30503-4
    DOI: 10.1038/s41467-022-30503-4
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    References listed on IDEAS

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    1. Mingsong Wang & Alex Krasnok & Sergey Lepeshov & Guangwei Hu & Taizhi Jiang & Jie Fang & Brian A. Korgel & Andrea Alù & Yuebing Zheng, 2020. "Suppressing material loss in the visible and near-infrared range for functional nanophotonics using bandgap engineering," Nature Communications, Nature, vol. 11(1), pages 1-9, December.
    2. Tim Burgess & Dhruv Saxena & Sudha Mokkapati & Zhe Li & Christopher R. Hall & Jeffrey A. Davis & Yuda Wang & Leigh M. Smith & Lan Fu & Philippe Caroff & Hark Hoe Tan & Chennupati Jagadish, 2016. "Doping-enhanced radiative efficiency enables lasing in unpassivated GaAs nanowires," Nature Communications, Nature, vol. 7(1), pages 1-7, September.
    3. L. Pavesi & L. Dal Negro & C. Mazzoleni & G. Franzò & F. Priolo, 2000. "Optical gain in silicon nanocrystals," Nature, Nature, vol. 408(6811), pages 440-444, November.
    4. Chengyun Zhang & Yi Xu & Jin Liu & Juntao Li & Jin Xiang & Hui Li & Jinxiang Li & Qiaofeng Dai & Sheng Lan & Andrey E. Miroshnichenko, 2018. "Lighting up silicon nanoparticles with Mie resonances," Nature Communications, Nature, vol. 9(1), pages 1-7, December.
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