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硅基电光调制与模分复用集成器件 被引量:9

Silicon-Based Integrated Device for Electro-Optic Modulation Assembly with Mode-Division Multiplexing
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摘要 提出了一种硅基电光调制与模分复用的集成器件,该集成器件的电光调制模块由硅基光子晶体波导和宽度调制(WM)型谐振腔组成,模分复用模块由硅基非对称平行纳米线波导组成。光子晶体波导和纳米线波导的连接处采用锥形结构,用于减少两种波导之间的级联损耗。根据时域耦合模理论与等离子体色散效应,采用WM型谐振腔和PN掺杂结构实现了对TE0模式的调制。根据横向耦合模理论,采用非对称平行纳米线波导实现了TE0模向TE1模的转换。应用二维时域有限差分法(2D-FDTD)对其性能进行仿真分析,结果表明,该集成器件在调制电压为1.24V时,可以实现中心波长为1553.91nm的TE0模和TE1模的窄带通断调制及复用功能,插入损耗小于0.46 dB,消光比为19.73 dB,调制深度为0.9894,高品质因数Q值达1.5×10^(4),信道串扰小于-14.66 dB.该集成器件的结构紧凑,尺寸约为54μm×22μm,这对提高系统集成度、提升光通信网络容量具有重要意义。 Objective As the package size of high-speed optical communication devices becomes smaller,and the performance requirements get higher,it is not easy for traditional electro-optic modules with separated components to meet the demands of modern communication.Currently,electro-optic devices are developing toward highly integrated miniaturization.There have been many studies on photonic-crystal-based electro-optic modulators and silicon-based mode division multiplexers.However,there are few studies on the integration of the two devices.During the evolution of optical communications in the future,the demands for small size,large-capacity,and high integra tion have become increasingly prominent.Thus,we propose a silicon based integrated device for electro-optic modulation assembly with mode division multiplexing,which has low insertion loss,low channel crosstalk,high extinction ratio,and large modula tion depth.The integrated device has a compact structure and excellent performance.It has broad application prospects in the field of high-speed and large-capacity optical communication and optoelectronic integration.Methods The proposed integrated device consists of electro-optic modulation and mode division multiplexing modules.The electro-optic modulation module consists of silicon-based photonic crystal waveguides and a width-modulated(WM)resonant cavity.The mode division multiplexing module consists of silicon-based asymmetric parallel nanowire waveguides.A tapered structure is used at the junction of photonic crystal and nanowire waveguides to reduce the cascade loss between the two waveguides.We used the finite-different time-domain(FDTD)and device methods in the commercial optical simulation software Lumerical for simulation analysis.According to the time-domain coupled-mode theory and plasma dispersion effect,WM-type resonant cavity and PN doping structure are used to achieve the on-off modulation of TE0 mode.According to the transverse coupled-mode theory,asymmetric parallel nanowire waveguides are used to achieve the conversion from TE0 to TE1 modes.The integrated device can achieve a narrow-band on-off modulation and mode multiplexing function of TE0 and TE1 modes with a center wavelength of 1553.91 nm.Results and Discussions The integrated device has excellent performance.To achieve low insertion loss,a tapered structure with C=9 is selected using simulation analysis to cascade photonic crystal slab and nanowire waveguides.The proposed structure can achieve narrow-band on-off modulation and mode division multiplexing for TE0 and TE1 modes with a center wavelength of 1553.91 nm.When the modulation voltage is 1.24 V,the variation of electron concentration△Ne reaches 4.55×10^(18)cm^(3),and the variation of hole concentration△Ne reaches 5×10^(18)cm^(-3)(Fig.12).The transmittance of the integrated device under“off”and“on”states are T=0.010255%and T=96.34%,respectively(Fig.13),and the Q value reaches 1.5×10^(4).The extinction ratio of the integrated device is 19.73 dB,and the modulation depth is 0.9894.Through detection on ports A,B,3,and 4,the.performance parameters of each mode at output ports are measured.The calculation results showed that the minimum and maximum insertion losses of the integrated device are 0.05 dB and 0.46 dB,respectively.The minimum and maximum channel crosstalk are-34.33 dB and-14.66 dB,respectively.Besides,after comparing the performance of the photonic crystal electro-optic modulators and two-mode silicon-based mode division multiplexers proposed in the existing references(Table 1),the proposed device can integrate the electro optic modulation and mode division multiplexing modules.Besides,the proposed device has excellent performance.Conclusions This study proposed a silicon-based integrated device for electro-optic modulation assembly with mode division multiplexing.WM-type photonic crystal resonator and silicon-based asymmetric parallel nanowire waveguides.can be used to achieve on-off modulation and mode division multiplexing.The tapered structure can reduce the cascading loss between photonic crystal and nanowire waveguides.The proposed integrated device can achieve a narrow-band on-off modulation and multiplexing function of TE0 and TE1 modes with a center wavelength of 1553.91 nm.When the modulation voltage is 1.24 V,it can achieve low insertion loss,low channel crosstalk,high extinction ratio,large modulation depth,and high Q value.The extinction ratio of the integrated device is 19.73 dB,and the modulation depth is 0.9894.The minimum and maximum insertion losses of the integrated device are 0.05 dB and 0.46 dB,respectively.The minimum and maximum channel crosstalk are-34.33 dB and-14.66 dB,respectively.It hasa compact size of~54 μm×22μm.It can be applied to high-speed and large capacity optical communication systems and has significant value for improving system integration.
作者 项彤 陈鹤鸣 胡宇宸 Xiang Tong;Chen Heming;Hu Yuchen(College of Electronic and Optical Engineering,Nanjing University of Posts and Telecommunications,Nanjing,Jiangsu 210023,China;Bell Honors School,Nanjing University of Posts and Telecommunications,Nanjing,Jiangsu 210023,China)
出处 《中国激光》 EI CAS CSCD 北大核心 2021年第11期131-142,共12页 Chinese Journal of Lasers
基金 国家自然科学基金(61571237) 江苏省自然科学基金(BK20151509)。
关键词 光通信 硅基光子晶体 耦合模理论 电光调制 模分复用 集成器件 optical communica tions silicon-based photonic crystal coupling mode theory electro-optic modulation mode division multiplexing integrated device
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