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    Journals >Infrared and Laser Engineering >Volume 51 >Issue 5 >Page 20220214 > Article
    • Infrared and Laser Engineering
    • Vol. 51, Issue 5, 20220214 (2022)
    Fabrication of silicon nitride-based integrated microcavity optical frequency comb devices (Invited)
    Zhendong Zhu1, Pingwei Lin1, Zhaoyang Sun2, Benfeng Bai2, and Xueshen Wang1
    Author Affiliations
  • 1National Institute of Metrology, Beijing 100029, China
  • 2Department of Precision Instrument, Tsinghua University, Beijing 100084, China
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    DOI: 10.3788/IRLA20220214 Cite this Article
    Zhendong Zhu, Pingwei Lin, Zhaoyang Sun, Benfeng Bai, Xueshen Wang. Fabrication of silicon nitride-based integrated microcavity optical frequency comb devices (Invited)[J]. Infrared and Laser Engineering, 2022, 51(5): 20220214 Copy Citation Text show less
    (a) A modified Damascene process for the fabrication of Si3N4 film; (b)-(c) Atomic force microscope analysis of silicon nitride film grown by LPCVD; (d) Absorption spectrum of the grown Si3N4 film
    Fig. 1. (a) A modified Damascene process for the fabrication of Si3N4 film; (b)-(c) Atomic force microscope analysis of silicon nitride film grown by LPCVD; (d) Absorption spectrum of the grown Si3N4 film
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    Defects of microresonators produced from the processing with or without the Damascene microstructures. (a) Tiny crack on microrings and waveguides from stress conducting; (b) Bubbles at the bottom of micoring and waveguide; (c) Broken defects of the waveguide at the coupling area of waveguide/conterpart microring; (d) No defects with Damascene microstructures
    Fig. 2. Defects of microresonators produced from the processing with or without the Damascene microstructures. (a) Tiny crack on microrings and waveguides from stress conducting; (b) Bubbles at the bottom of micoring and waveguide; (c) Broken defects of the waveguide at the coupling area of waveguide/conterpart microring; (d) No defects with Damascene microstructures
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    (a) Si3N4 microresonator fabricated by the modified Damascene microstructure; (b) Cross-section profile of the critical coupling area between ring microcavity and conterpart waveguide
    Fig. 3. (a) Si3N4 microresonator fabricated by the modified Damascene microstructure; (b) Cross-section profile of the critical coupling area between ring microcavity and conterpart waveguide
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    Light path for measuring the optical frequency combs by dual-pumping
    Fig. 4. Light path for measuring the optical frequency combs by dual-pumping
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    Comb spectra. (a) Chaotic state comb; (b) Soliton state comb matched with sech2 function fitting
    Fig. 5. Comb spectra. (a) Chaotic state comb; (b) Soliton state comb matched with sech2 function fitting
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    Zhendong Zhu, Pingwei Lin, Zhaoyang Sun, Benfeng Bai, Xueshen Wang. Fabrication of silicon nitride-based integrated microcavity optical frequency comb devices (Invited)[J]. Infrared and Laser Engineering, 2022, 51(5): 20220214
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