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Mercury Telluride Quantum Dot Based Phototransistor Enabling High-Sensitivity Room-Temperature Photodetection at 2000 nm.

Mercury Telluride Quantum Dot Based Phototransistor Enabling High-Sensitivity Room-Temperature Photodetection at 2000 nm.
Mercury Telluride Quantum Dot Based Phototransistor Enabling High-Sensitivity Room-Temperature Photodetection at 2000 nm.
Near-to-mid-infrared photodetection technologies could be widely deployed to advance the infrastructures of surveillance, environmental monitoring, and manufacturing, if the detection devices are low-cost, in compact format, and with high performance. For such application requirements, colloidal quantum dot (QD) based photodetectors stand out as particularly promising due to the solution processability and ease of integration with silicon technologies; unfortunately, the detectivity of the QD photodetectors toward longer wavelengths has so far been low. Here we overcome this performance bottleneck through synergistic efforts between synthetic chemistry and device engineering. First, we developed a fully automated aprotic solvent, gas-injection synthesis method that allows scalable fabrication of large sized HgTe QDs with high quality, exhibiting a record high photoluminescence quantum yield of 17% at the photoluminescence peak close to 2.1 μm. Second, through gating a phototransistor structure we demonstrate room-temperature device response to reach >2 × 1010 cm Hz1/2 W–1 (at 2 kHz modulation frequency) specific detectivity beyond the 2 μm wavelength range, which is comparable to commercial epitaxial-grown photodetectors. To demonstrate the practical application of the QD phototransistor, we incorporated the device in a carbon monoxide gas sensing system and demonstrated reliable measurement of gas concentration. This work represents an important step forward in commercializing QD-based infrared detection technologies.
1936-0851
5614-5622
Chen, Mengyu
2ac8bd5e-cbf1-4d9a-adcb-65dedf244b9b
Lu, Haipeng
3d7c997c-0917-4475-b360-e080bde43841
Abdelazim, Nema
2ac8bd5e-cbf1-4d9a-adcb-65dedf244b9b
Zhu, Ye
b20d18f4-b0e0-4202-b5fc-dcc26840489c
Wang, Zhen
2db605ac-4c53-40c7-aa37-3bb87c7b4243
Ren, Wei
b3d0acfa-0a2b-4807-9830-fdb264df3b90
Kershaw, Stephen V.
28b7b4a5-6537-407c-956e-3394525f0b77
Rogach, Andrey L.
55ffa495-10cb-4fee-8d90-d4907acf4207
Zhao, Ni
04847861-7874-472c-ac95-317696c89a6e
Chen, Mengyu
2ac8bd5e-cbf1-4d9a-adcb-65dedf244b9b
Lu, Haipeng
3d7c997c-0917-4475-b360-e080bde43841
Abdelazim, Nema
2ac8bd5e-cbf1-4d9a-adcb-65dedf244b9b
Zhu, Ye
b20d18f4-b0e0-4202-b5fc-dcc26840489c
Wang, Zhen
2db605ac-4c53-40c7-aa37-3bb87c7b4243
Ren, Wei
b3d0acfa-0a2b-4807-9830-fdb264df3b90
Kershaw, Stephen V.
28b7b4a5-6537-407c-956e-3394525f0b77
Rogach, Andrey L.
55ffa495-10cb-4fee-8d90-d4907acf4207
Zhao, Ni
04847861-7874-472c-ac95-317696c89a6e

Chen, Mengyu, Lu, Haipeng, Abdelazim, Nema, Zhu, Ye, Wang, Zhen, Ren, Wei, Kershaw, Stephen V., Rogach, Andrey L. and Zhao, Ni (2017) Mercury Telluride Quantum Dot Based Phototransistor Enabling High-Sensitivity Room-Temperature Photodetection at 2000 nm. ACS Nano, 11 (6), 5614-5622. (doi:10.1021/acsnano.7b00972).

Record type: Article

Abstract

Near-to-mid-infrared photodetection technologies could be widely deployed to advance the infrastructures of surveillance, environmental monitoring, and manufacturing, if the detection devices are low-cost, in compact format, and with high performance. For such application requirements, colloidal quantum dot (QD) based photodetectors stand out as particularly promising due to the solution processability and ease of integration with silicon technologies; unfortunately, the detectivity of the QD photodetectors toward longer wavelengths has so far been low. Here we overcome this performance bottleneck through synergistic efforts between synthetic chemistry and device engineering. First, we developed a fully automated aprotic solvent, gas-injection synthesis method that allows scalable fabrication of large sized HgTe QDs with high quality, exhibiting a record high photoluminescence quantum yield of 17% at the photoluminescence peak close to 2.1 μm. Second, through gating a phototransistor structure we demonstrate room-temperature device response to reach >2 × 1010 cm Hz1/2 W–1 (at 2 kHz modulation frequency) specific detectivity beyond the 2 μm wavelength range, which is comparable to commercial epitaxial-grown photodetectors. To demonstrate the practical application of the QD phototransistor, we incorporated the device in a carbon monoxide gas sensing system and demonstrated reliable measurement of gas concentration. This work represents an important step forward in commercializing QD-based infrared detection technologies.

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Accepted/In Press date: 19 May 2017
e-pub ahead of print date: 5 June 2017
Published date: 27 June 2017

Identifiers

Local EPrints ID: 452858
URI: http://eprints.soton.ac.uk/id/eprint/452858
ISSN: 1936-0851
PURE UUID: e036c68c-c477-4074-bfd6-ba11a7325d60

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Date deposited: 21 Dec 2021 17:57
Last modified: 16 Mar 2024 14:22

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Contributors

Author: Mengyu Chen
Author: Haipeng Lu
Author: Nema Abdelazim
Author: Ye Zhu
Author: Zhen Wang
Author: Wei Ren
Author: Stephen V. Kershaw
Author: Andrey L. Rogach
Author: Ni Zhao

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