Ultra‐Compact High‐Speed Polarization Division Multiplexing Optical Receiving Chip Enabled by Graphene‐on‐Plasmonic Slot Waveguide Photodetectors

Wang, Yilun; Zhang, Yong; Jiang, Zhibin; Deng, Wentao; Zhou, De; Huang, Xinyu; Yan, Qizhi; Zhang, Jihua; Chen, Liao; Yu, Yu; Li, Xiang; Ye, Lei; Zhang, Chi

doi:10.1002/adom.202001215

Cited by 21 publications

(17 citation statements)

References 51 publications

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“…Currently, plasmonic waveguide-integrated graphene-based PDs with a compact size of a few microns 20 , 21 show a high responsivity up to 0.7 A/W 21 , a large bandwidth of 110 GHz 20 , 22 , and a high receiving capacity of 100–120 Gbit/s 20 , 26 , 27 . However, graphene-based PDs are still difficult to be applied in 200-Gbit/s, 400-Gbit/s, or even higher 800-Gbit/s optical interconnections 28 , while direct detection mode is exploited.…”

Section: Introductionmentioning

confidence: 99%

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Ultrahigh-speed graphene-based optical coherent receiver

Wang

Jiang

et al. 2021

Nat Commun

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Graphene-based photodetectors have attracted significant attention for high-speed optical communication due to their large bandwidth, compact footprint, and compatibility with silicon-based photonics platform. Large-bandwidth silicon-based optical coherent receivers are crucial elements for large-capacity optical communication networks with advanced modulation formats. Here, we propose and experimentally demonstrate an integrated optical coherent receiver based on a 90-degree optical hybrid and graphene-on-plasmonic slot waveguide photodetectors, featuring a compact footprint and a large bandwidth far exceeding 67 GHz. Combined with the balanced detection, 90 Gbit/s binary phase-shift keying signal is received with a promoted signal-to-noise ratio. Moreover, receptions of 200 Gbit/s quadrature phase-shift keying and 240 Gbit/s 16 quadrature amplitude modulation signals on a single-polarization carrier are realized with a low additional power consumption below 14 fJ/bit. This graphene-based optical coherent receiver will promise potential applications in 400-Gigabit Ethernet and 800-Gigabit Ethernet technology, paving another route for future high-speed coherent optical communication networks.

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Section: Introductionmentioning

confidence: 99%

“…Here, we present a single-polarization graphene-based OCR enabled by plasmonic slot waveguides (PSWs) with compact active detection sections of 4 × 15 μm × 100 nm (four graphene-on-PSW PDs 26 with an active detection area of 15 μm × 100 nm each (see Supplementary Note 1 and Supplementary Fig. 3 )) and a simple fabrication process.…”

Section: Introductionmentioning

confidence: 99%

Ultrahigh-speed graphene-based optical coherent receiver

Wang

Jiang

et al. 2021

Nat Commun

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“…3(b) and 3(c). We could see that the current decreases with light injection, which is a direct phenomenon indicating that the dominant photodetection mechanism within the proposed device should be the photobolometric effect 21,22,48 . Based on the measured I-V curve, the relationship between the photocurrent and the bias voltage (V B ) is depicted in Fig.…”

Section: J O U R N a L P R E -P R O O Fmentioning

confidence: 79%

Graphene photodetector employing double slot structure with enhanced responsivity and large bandwidth

Yan¹,

Zuo²,

Xiao³

et al. 2022

OEA

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Silicon photonics integrated with graphene provides a promising solution to realize integrated photodetectors operating at the communication window thanks to graphene's ultrafast response and compatibility with CMOS fabrication process. However, current hybrid graphene/silicon photodetectors suffer from low responsivity due to the weak light-graphene interaction. Plasmonic structures have been explored to enhance the responsivity, but the intrinsic metallic Ohmic absorption of the plasmonic mode limits its performance. In this work, by combining the silicon slot and the plasmonic slot waveguide, we demonstrate a novel double slot structure supporting high-performance photodetection, taking advantages of both silicon photonics and plasmonics. With the optimized structural parameters, the double slot structure significantly promotes graphene absorption while maintaining low metallic absorption within the double slot waveguide. Based on the double slot structure, the demonstrated photodetector holds a high responsivity of 603.92 mA/W and a large bandwidth of 78 GHz. The high-performance photodetector provides a competitive solution for the silicon photodetector. Moreover, the double slot structure could be beneficial to a broader range of hybrid two-dimensional material/silicon devices to achieve stronger light-matter interaction with lower metallic absorption.

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“…TiN is a refractory metal nitride that has optical properties that are similar to Au [21], an electrical conductivity higher than Titanium (Ti) [22], but unlike Au, TiN is CMOS-compatible [20], [23]- [25]. A strong plasmonic enhancement of the optical mode has been reported for photodetectors that are based on plasmonic slot waveguides [5], [11], [13], [26], including the aforementioned graphene photodetector with a record-high responsivity of 0.67 A/W. By incorporating these design elements, we report a photodetector device that achieves a high responsivity of 2.18 A/W and more at 0.5 V bias, across the telecom C-band and beyond.…”

Section: Introductionmentioning

confidence: 99%

Plasmonic Photovoltaic Double-Graphene Detector Integrated Into TiN Slot Waveguides

Alaloul

Khurgin

2021

IEEE Photonics J.

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Graphene has emerged as an ultrafast photonic material for on-chip photodetection. However, its atomic thickness limits its interaction with guided optical modes, which in turn weakens the photoresponse of waveguide-integrated graphene photodetectors. Nonetheless, it is possible to enhance the interaction of guided light with graphene by nanophotonic means. Herein, we propose a practical design of a plasmon-enhanced photovoltaic double-graphene detector that is integrated into 5 µm long titanium nitride slot waveguides. The use of double-graphene in this configuration yields a high responsivity of 2.18 A/W and more for a 0.5 V bias, across the telecom C-band and beyond. Moreover, the device operates at an ultra-high-speed beyond 100 GHz with an ultra-low noise equivalent power of < 35 pW/ √ Hz. The reported features are highly promising and are expected to serve the needs of next-generation optical interconnects.

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Ultra‐Compact High‐Speed Polarization Division Multiplexing Optical Receiving Chip Enabled by Graphene‐on‐Plasmonic Slot Waveguide Photodetectors

Cited by 21 publications

References 51 publications

Ultrahigh-speed graphene-based optical coherent receiver

Ultrahigh-speed graphene-based optical coherent receiver

Graphene photodetector employing double slot structure with enhanced responsivity and large bandwidth

Plasmonic Photovoltaic Double-Graphene Detector Integrated Into TiN Slot Waveguides

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