Colloidal Quantum-Dots/Graphene/Silicon Dual-Channel Detection of Visible Light and Short-Wave Infrared

Xin Tang; Menglu Chen; Ananth Kamath; Matthew M. Ackerman; Philippe Guyot-Sionnest

doi:10.1021/acsphotonics.0c00247

Colloidal Quantum-Dots/Graphene/Silicon Dual-Channel Detection of Visible Light and Short-Wave Infrared

Xin Tang, Menglu Chen, Ananth Kamath, Matthew M. Ackerman, Philippe Guyot-Sionnest^*

^*Corresponding author for this work

The University of Chicago

Research output: Contribution to journal › Article › peer-review

47 Citations (Scopus)

Abstract

Integration of infrared detectors with current silicon-based imagers would not only extend their spectral sensing range, but also enables numerous applications including thermal imaging, machine vision, and spectrometers. Here, we report the development of a dual-channel photodetector by depositing a colloidal quantum dot (CQDs) infrared photodiode onto a graphene/p-silicon Schottky junction to provide simultaneous visible and infrared photoresponse channels. The HgTe photodiode is patterned into a semitransparent mesh structure with varying fill factors so that the visible light reaches the silicon substrate. The graphene/silicon Schottky junction has a responsivity of ∼0.9 A/W in the visible and the infrared CQDs photodiode has a detectivity of ∼5 × 109 Jones at 2.4 μm for a filling factor of 0.1.

Original language	English
Pages (from-to)	1117-1121
Number of pages	5
Journal	ACS Photonics
Volume	7
Issue number	5
DOIs	https://doi.org/10.1021/acsphotonics.0c00247
Publication status	Published - 20 May 2020
Externally published	Yes

Keywords

colloidal quantum dots
dual-channel photodetectors
graphene/silicon Schottky junction
visible/infrared

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10.1021/acsphotonics.0c00247

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title = "Colloidal Quantum-Dots/Graphene/Silicon Dual-Channel Detection of Visible Light and Short-Wave Infrared",

abstract = "Integration of infrared detectors with current silicon-based imagers would not only extend their spectral sensing range, but also enables numerous applications including thermal imaging, machine vision, and spectrometers. Here, we report the development of a dual-channel photodetector by depositing a colloidal quantum dot (CQDs) infrared photodiode onto a graphene/p-silicon Schottky junction to provide simultaneous visible and infrared photoresponse channels. The HgTe photodiode is patterned into a semitransparent mesh structure with varying fill factors so that the visible light reaches the silicon substrate. The graphene/silicon Schottky junction has a responsivity of ∼0.9 A/W in the visible and the infrared CQDs photodiode has a detectivity of ∼5 × 109 Jones at 2.4 μm for a filling factor of 0.1.",

keywords = "colloidal quantum dots, dual-channel photodetectors, graphene/silicon Schottky junction, visible/infrared",

author = "Xin Tang and Menglu Chen and Ananth Kamath and Ackerman, {Matthew M.} and Philippe Guyot-Sionnest",

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AU - Tang, Xin

AU - Chen, Menglu

AU - Kamath, Ananth

AU - Ackerman, Matthew M.

AU - Guyot-Sionnest, Philippe

PY - 2020/5/20

Y1 - 2020/5/20

N2 - Integration of infrared detectors with current silicon-based imagers would not only extend their spectral sensing range, but also enables numerous applications including thermal imaging, machine vision, and spectrometers. Here, we report the development of a dual-channel photodetector by depositing a colloidal quantum dot (CQDs) infrared photodiode onto a graphene/p-silicon Schottky junction to provide simultaneous visible and infrared photoresponse channels. The HgTe photodiode is patterned into a semitransparent mesh structure with varying fill factors so that the visible light reaches the silicon substrate. The graphene/silicon Schottky junction has a responsivity of ∼0.9 A/W in the visible and the infrared CQDs photodiode has a detectivity of ∼5 × 109 Jones at 2.4 μm for a filling factor of 0.1.

AB - Integration of infrared detectors with current silicon-based imagers would not only extend their spectral sensing range, but also enables numerous applications including thermal imaging, machine vision, and spectrometers. Here, we report the development of a dual-channel photodetector by depositing a colloidal quantum dot (CQDs) infrared photodiode onto a graphene/p-silicon Schottky junction to provide simultaneous visible and infrared photoresponse channels. The HgTe photodiode is patterned into a semitransparent mesh structure with varying fill factors so that the visible light reaches the silicon substrate. The graphene/silicon Schottky junction has a responsivity of ∼0.9 A/W in the visible and the infrared CQDs photodiode has a detectivity of ∼5 × 109 Jones at 2.4 μm for a filling factor of 0.1.

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Colloidal Quantum-Dots/Graphene/Silicon Dual-Channel Detection of Visible Light and Short-Wave Infrared

Abstract

Keywords

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