Design of a carrier-depletion Mach-Zehnder modulator in 250 nm silicon-on-insulator technology

IF 0.9 Q4 ENGINEERING, ELECTRICAL & ELECTRONIC

Advances in Radio Science Pub Date : 2017-12-05 DOI:10.5194/ARS-15-269-2017

M. F. Rosa, L. Rathgeber, R. Elster, N. Hoppe, Thomas Fohn, Martin Schmidt, W. Vogel, M. Berroth

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引用次数: 16

Abstract

Abstract. We present the design of a single-drive Mach-Zehnder modulator for amplitude modulation in silicon-on-insulator technology with 250 nm active layer thickness. The applied RF signal modulates the carrier density in a reverse biased lateral pn-junction. The free carrier plasma dispersion effect in silicon leads to a change in the refractive index. The modulation efficiency and the optical loss due to free carriers are analyzed for different doping configurations. The intrinsic electrical parameters of the pn-junction of the phase shifter like resistance and capacitance and the corresponding RC-limit are studied. A first prototype in this technology fabricated at the IMS CHIPS Stuttgart is successfully measured. The structure has a modulation efficiency of VπL = 3.1 V ⋅ cm at 2 V reverse bias. The on-chip insertion loss is 4.2 dB. The structure exhibits an extinction ratio of around 32 dB. The length of the phase shifter is 0.5 mm. The cutoff frequency of the entire modulator is 30 GHz at 2 V. Finally, an optimization of the doping structure is presented to reduce the optical loss and to improve the modulation efficiency. The optimized silicon optical modulator shows a theoretical modulation efficiency of VπL = 1.8 V ⋅ cm at 6 V bias and a maximum optical loss due to the free carrier absorption of around 3.1 dB cm−1. An ultra-low fiber-to-fiber loss of approximately 4.8 dB is expected using the state of the art optical components in the used technology.

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250nm绝缘体上硅技术中载流子耗尽Mach-Zehnder调制器的设计

摘要我们设计了一种单驱动Mach-Zehnder调制器，用于250 纳米有源层厚度的绝缘体上硅技术的调幅。所施加的射频信号调制载波密度在一个反向偏置的横向pn结。硅中的自由载流子等离子体色散效应导致了折射率的变化。分析了不同掺杂结构下自由载流子的调制效率和光损耗。研究了移相器pn结的电阻、电容等本征电学参数及其rc极限。在斯图加特IMS CHIPS制造的该技术的第一个原型已成功测量。该结构在2 V反向偏压下的调制效率为Vπ l = 3.1 V⋅cm。片内插入损耗为4.2 dB。该结构的消光比约为32 dB。移相器的长度为0.5 mm。整个调制器在2 V时的截止频率为30 GHz。最后，对掺杂结构进行了优化，以降低光损耗，提高调制效率。优化后的硅光调制器在6 V偏置下的理论调制效率为Vπ l = 1.8 V⋅cm，自由载流子吸收的最大光损耗约为3.1 dB cm−1。使用该技术中最先进的光学元件，预计光纤到光纤的损耗约为4.8 dB。

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