High Bandwidth and Ultra-low Dark Current Ge Photodetector Enabled by Frequency Domain Equalization

Abstract

High bandwidth and low dark current germanium (Ge) photodetectors are crucial in silicon photonic integrated circuits. The bandwidth of Ge photodetectors is restricted by carrier transit time and parasitic parameters. And thermal generation of carriers within the Ge P-N junction results in an inherent dark current, typically in nA-μA range. Here, we propose an equalization photodetector (EqPD) utilizing the frequency response of a high-bandwidth photodetector PDA to subtract the frequency response of a low-bandwidth photodetector PDB. With the response of PDB attenuating more severely than PDA at high frequency, the differential response (the response of EqPD) can get higher values at high-frequency than at low-frequency. The dark current of EqPD can also be significantly reduced with PDB balancing the dark current of PDA. Experimental results show that the bandwidth of our proposed photodetector can be expanded to over 110 GHz with a dark current of 1 pA simultaneously, and its Non-Return-to-Zero (NRZ) transmission speed can reach 100 Gbaud without digital signal processing. To the best of our knowledge, this represents the highest bandwidth and lowest dark current in a vertical Ge photodetector. The high-performance EqPD provides a promising solution for high-speed and ultra-low noise photodetection in next-generation optical communication.

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