High-efficiency and high-speed germanium photodetector enabled by multiresonant photonic crystal

High-efficiency and high-speed germanium photodetector enabled by multiresonant photonic crystal

High-efficiency and high-speed photodetectors with broadband responses are playing pivotal roles for wavelength-division multiplexing optical communications. Germanium photodetectors on silicon platforms exhibit potential cost advantage due to the compatibility for monolithic integration with silico...

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Bibliographic Details
Published in:Nanophotonics (Berlin, Germany) Vol. 10; no. 3; pp. 1081 - 1087
Main Authors: Song, Jinwen, Yuan, Shuai, Cui, Chengcong, Wang, Yuxi, Li, Zhiyong, Wang, Alan X., Zeng, Cheng, Xia, Jinsong
Format: Journal Article
Language:English
Published: Berlin De Gruyter 01-05-2021
Walter de Gruyter GmbH
Subjects:
Bandwidths
Broadband
C band
Circuits
Crystal structure
Diameters
Efficiency
Electronic circuits
Germanium
germanium photodetector
guided-mode resonance
High speed
high-efficiency
Optical communication
Optical interconnects
Photometers
photonic crystal
Photonic crystals
Quantum efficiency
Signal processing
Silicon
Thickness
Wavelength division multiplexing
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Summary:High-efficiency and high-speed photodetectors with broadband responses are playing pivotal roles for wavelength-division multiplexing optical communications. Germanium photodetectors on silicon platforms exhibit potential cost advantage due to the compatibility for monolithic integration with silicon-based electronic circuits for signal amplification and processing. In this article, we report a normal incidence, germanium photodetector enabled by guided-mode resonances in photonic crystal, which successfully resolved the compromise between quantum efficiency, wavelength coverage and bandwidth requirement, a drawback usually faced by conventional photodetectors operating at normal incidence. The resonant photonic crystal structure is designed to support multiple resonances in the target wavelength range. With an intrinsic absorption layer thickness of 350 nm, the device achieved a high external quantum efficiency of 50% at 1550 nm, along with an enhancement around 300% for the entire C-band. Using a mesa diameter of 14 μm, the fabricated device exhibited a 3-dB bandwidth of 33 GHz and obtained clear eye diagrams at bit rate up to 56 Gbps. This work provides a promising method to design high-efficiency, high-speed, normal incidence germanium photodetectors for optical interconnect systems.
ISSN:2192-8606
2192-8614
DOI:10.1515/nanoph-2020-0455