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CLC number: O439

On-line Access: 2024-08-27

Received: 2023-10-17

Revision Accepted: 2024-05-08

Crosschecked: 2019-04-11

Cited: 0

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Citations:  Bibtex RefMan EndNote GB/T7714

 ORCID:

Chen-lei Li

http://orcid.org/0000-0002-6759-3846

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Frontiers of Information Technology & Electronic Engineering  2019 Vol.20 No.4 P.498-506

http://doi.org/10.1631/FITEE.1800386


Ten-channel mode-division-multiplexed silicon photonic integrated circuit with sharp bends


Author(s):  Chen-lei Li, Xiao-hui Jiang, Yung Hsu, Guan-hong Chen, Chi-wai Chow, Dao-xin Dai

Affiliation(s):  Centre for Optical and Electromagnetic Research, State Key Laboratory for Modern Optical Instrumentation, College of Optical Science and Engineering, Zhejiang University, Hangzhou 310058, China; more

Corresponding email(s):   lichenlei@zju.edu.cn, xiaohuijiang@zju.edu.cn, matrtihewl0937@gmail.com, sscssc82@yahoo.com.tw, cwchow@faculty.nctu.edu.tw, dxdai@zju.edu.cn

Key Words:  Silicon, Multimode, Waveguide, Euler-bends


Chen-lei Li, Xiao-hui Jiang, Yung Hsu, Guan-hong Chen, Chi-wai Chow, Dao-xin Dai. Ten-channel mode-division-multiplexed silicon photonic integrated circuit with sharp bends[J]. Frontiers of Information Technology & Electronic Engineering, 2019, 20(4): 498-506.

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Abstract: 
A multimode silicon photonic integrated circuit (PIC) comprising a pair of on-chip mode (de)multiplexers with 10-mode channels and a multimode bus waveguide with sharp bends is demonstrated to enable multi-channel on-chip transmissions. The core width of the multimode bus waveguide is chosen such that it can support 10 guided modes, of which there are four transverse-magnetic polarization modes and six transverse-electric polarization modes. This multimode bus waveguide comprises sharp bends based on modified Euler curves. Experimental results demonstrate that the present silicon PIC enables the 10-channel on-chip transmission with a low inter-mode crosstalk of approximately −20 dB over a broad bandwidth of 1520–1610 nm even when the bending radius of the S-bend is as small as 40 μm. Compared with a silicon PIC using a conventional arc-bend with the same bending radius, our proposed PIC demonstrates a significant improvement.

具有超小弯曲半径的10通道硅基集成模分复用器件

摘要:为实现多通道片上信号传输,设计一种多模硅光集成器件(PIC),包括一对10通道片上模式多路复用-解复用器以及具有超小弯曲半径的总线波导。选择多模总线波导宽度使其能支持10种模式,其中包括4种横磁(TM)和6种横电(TE)偏振模式。多模总线波导由基于修正的欧拉曲线超小弯曲半径组成。实验结果表明,即使组成总线波导的弯曲半径仅为40µm,该芯片仍可在大带宽1520−1610 nm上实现10通道传输,且具有约−20 dB的低模间串扰。与传统弯曲半径相同的圆弧弯曲相比,该集成器件有明显优势。

关键词:硅;多模;光波导;欧拉曲线

Darkslateblue:Affiliate; Royal Blue:Author; Turquoise:Article

Reference

[1]Barwicz T, Watts MR, Popović MA, et al., 2007. Polarization-transparent microphotonic devices in the strong confinement limit. Nat Photon, 1(1):57-60.

[2]Cherchi M, Ylinen S, Harjanne M, et al., 2013. Dramatic size reduction of waveguide bends on a micron-scale silicon photonic platform. Opt Expr, 21(15):17814-17823.

[3]Dai DX, 2014. Multimode optical waveguide enabling microbends with low inter-mode crosstalk for mode-multiplexed optical interconnects. Opt Expr, 22(22): 27524-27534.

[4]Dai DX, 2017. Silicon nanophotonic integrated devices for on-chip multiplexing and switching. J Lightw Technol, 35(4):572-587.

[5]Dai DX, Bowers JE, 2014. Silicon-based on-chip multiplexing technologies and devices for Peta-bit optical interconnects. Nanophotonics, 3(4-5):283-311.

[6]Dai DX, Wang J, He SL, 2013. Silicon multimode photonic integrated devices for on-chip mode-division-multiplexed optical interconnects. Prog Electromagn Res, 143:773-819.

[7]Dai DX, Li CL, Wang SP, et al., 2018. 10-channel-mode (de)multiplexer with dual polarizations. Laser Photon Rev, 12(1):1700109.

[8]Fujisawa T, Makino S, Sato T, et al., 2017. Low-loss, compact, and fabrication-tolerant Si-wire 90° waveguide bend using clothoid and normal curves for large scale photonic integrated circuits. Opt Expr, 25(8):9150-9159.

[9]Gabrielli LH, Liu D, Johnson SG, et al., 2012. On-chip transformation optics for multimode waveguide bends. Nat Commun, 3:1217.

[10]Jiang XH, Wu H, Dai DX, 2018. Low-loss and low-crosstalk multimode waveguide bend on silicon. Opt Expr, 26(13): 17680-17689.

[11]Paniccia MJ, 2011. A perfect marriage: optics and silicon. Opt Photon, 6(2):34-38.

[12]Richardson DJ, Fini JM, Nelson LE, 2013. Space-division multiplexing in optical fibres. Nat Photon, 7(5):354-362.

[13]Sun CL, Yu Y, Chen GY, et al., 2016. A novel sharply bent silicon multimode waveguide with ultrahigh mode extinction ratio. Optical Fiber Communications Conf and Exhibition, p.1-3.

[14]Sun CL, Yu Y, Chen GY, et al., 2017. Ultra-compact bent multimode silicon waveguide with ultralow inter-mode crosstalk. Opt Lett, 42(15):3004-3007.

[15]Wu H, Tan Y, Dai DX, 2017. Ultra-broadband high-performance polarizing beam splitter on silicon. Opt Expr, 25(6):6069-6075.

[16]Xu HN, Shi YC, 2018. Ultra-sharp multi-mode waveguide bending assisted with metamaterial-based mode converters. Laser Photon Rev, 12(3):1700240.

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