Blazed subwavelength grating coupler
Blazed subwavelength grating coupler
Short-wavelength mid-infrared (2–2.5 μm wave band) silicon photonics has been a growing area to boost the applications of integrated optoelectronics in free-space optical communications, laser ranging, and biochemical sensing. In this spectral region, multi-project wafer foundry services developed for the telecommunication band are easily adaptable with the low intrinsic optical absorption from silicon and silicon dioxide materials. However, light coupling techniques at 2–2.5 μm wavelengths, namely, grating couplers, still suffer from low efficiencies, mainly due to the moderated directionality and poor diffraction-field tailoring capability. Here, we demonstrate a foundry-processed blazed subwavelength coupler for high-efficiency, wide-bandwidth, and large-tolerance light coupling. We subtly design multi-step-etched hybrid subwavelength grating structures to significantly improve directionality, as well as an apodized structure to tailor the coupling strength for improving the optical mode overlap and backreflection. Experimental results show that the grating coupler has a recorded coupling efficiency of −4.53 dB at a wavelength of 2336 nm with a 3-dB bandwidth of ∼107 nm. The study opens an avenue to developing state-of-the-art light coupling techniques for short-wavelength mid-infrared silicon photonics.
189-195
Guo, Rongxiang
73ce3de9-1517-4ec1-9abf-ea10338ff1cc
Zhang, Shujiao
ebb251a5-54f8-4ce3-94f6-78591dc99d2c
Gao, Haoran
4f835c47-9ecb-476e-bd98-f3e6f068c66c
Murugan, Ganapathy Senthil
a867686e-0535-46cc-ad85-c2342086b25b
Liu, Tiegen
e1ee0e2e-5a99-4349-96d1-df59a824319f
Cheng, Zhenzhou
a1edd543-2575-4783-af6d-fd9ea9d0ead9
23 January 2023
Guo, Rongxiang
73ce3de9-1517-4ec1-9abf-ea10338ff1cc
Zhang, Shujiao
ebb251a5-54f8-4ce3-94f6-78591dc99d2c
Gao, Haoran
4f835c47-9ecb-476e-bd98-f3e6f068c66c
Murugan, Ganapathy Senthil
a867686e-0535-46cc-ad85-c2342086b25b
Liu, Tiegen
e1ee0e2e-5a99-4349-96d1-df59a824319f
Cheng, Zhenzhou
a1edd543-2575-4783-af6d-fd9ea9d0ead9
Guo, Rongxiang, Zhang, Shujiao, Gao, Haoran, Murugan, Ganapathy Senthil, Liu, Tiegen and Cheng, Zhenzhou
(2023)
Blazed subwavelength grating coupler.
Photonics Research, 11 (2), .
(doi:10.1364/PRJ.474199).
Abstract
Short-wavelength mid-infrared (2–2.5 μm wave band) silicon photonics has been a growing area to boost the applications of integrated optoelectronics in free-space optical communications, laser ranging, and biochemical sensing. In this spectral region, multi-project wafer foundry services developed for the telecommunication band are easily adaptable with the low intrinsic optical absorption from silicon and silicon dioxide materials. However, light coupling techniques at 2–2.5 μm wavelengths, namely, grating couplers, still suffer from low efficiencies, mainly due to the moderated directionality and poor diffraction-field tailoring capability. Here, we demonstrate a foundry-processed blazed subwavelength coupler for high-efficiency, wide-bandwidth, and large-tolerance light coupling. We subtly design multi-step-etched hybrid subwavelength grating structures to significantly improve directionality, as well as an apodized structure to tailor the coupling strength for improving the optical mode overlap and backreflection. Experimental results show that the grating coupler has a recorded coupling efficiency of −4.53 dB at a wavelength of 2336 nm with a 3-dB bandwidth of ∼107 nm. The study opens an avenue to developing state-of-the-art light coupling techniques for short-wavelength mid-infrared silicon photonics.
Text
PR_Revised_MS_v3_AM
- Accepted Manuscript
More information
e-pub ahead of print date: 6 December 2022
Published date: 23 January 2023
Identifiers
Local EPrints ID: 475404
URI: http://eprints.soton.ac.uk/id/eprint/475404
ISSN: 2327-9125
PURE UUID: df9a7560-a081-497c-b6bc-02eb2a777baf
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Date deposited: 17 Mar 2023 17:31
Last modified: 17 Mar 2024 07:40
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Contributors
Author:
Rongxiang Guo
Author:
Shujiao Zhang
Author:
Haoran Gao
Author:
Ganapathy Senthil Murugan
Author:
Tiegen Liu
Author:
Zhenzhou Cheng
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