Suppression of dark current through barrier engineer for solution-processed colloidal quantum-dots infrared photodetectors

Zhenyu Jiang; Wenjia Hu; Yan Liu; Wenjun Zhang; Chen Mo; Guanjun You; Li Wang; Mahmoud R.M. Atalla; Yu Zhang; Jie Liu; Kandhar K. Kurhade; Jian Xu

doi:10.1063/1.4930158

Suppression of dark current through barrier engineer for solution-processed colloidal quantum-dots infrared photodetectors

Zhenyu Jiang, Wenjia Hu, Yan Liu, Wenjun Zhang, Chen Mo, Guanjun You, Li Wang, Mahmoud R.M. Atalla, Yu Zhang, Jie Liu, Kandhar K. Kurhade, Jian Xu

Electrical and Computer Engineering

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

9 Scopus citations

Abstract

In an attempt to suppress the dark current, the barrier layer engineer for solution-processed PbSe colloidal quantum-dot (CQD) photodetectors has been investigated in the present study. It was found that the dark current can be significantly suppressed by implementing two types of carrier blocking layers, namely, hole blocking layer and electron blocking layer, sandwiched in between two active PbSe CQD layers. Meanwhile no adverse impact has been observed for the photo current. Our study suggests that this improvement resides on the transport pathway created via carrier recombination at intermediate layer, which provides wide implications for the suppression of dark current for infrared photodetectors.

Original language	English (US)
Article number	091115
Journal	Applied Physics Letters
Volume	107
Issue number	9
DOIs	https://doi.org/10.1063/1.4930158
State	Published - Aug 25 2015

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© 2015 AIP Publishing LLC.

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title = "Suppression of dark current through barrier engineer for solution-processed colloidal quantum-dots infrared photodetectors",

abstract = "In an attempt to suppress the dark current, the barrier layer engineer for solution-processed PbSe colloidal quantum-dot (CQD) photodetectors has been investigated in the present study. It was found that the dark current can be significantly suppressed by implementing two types of carrier blocking layers, namely, hole blocking layer and electron blocking layer, sandwiched in between two active PbSe CQD layers. Meanwhile no adverse impact has been observed for the photo current. Our study suggests that this improvement resides on the transport pathway created via carrier recombination at intermediate layer, which provides wide implications for the suppression of dark current for infrared photodetectors.",

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doi = "10.1063/1.4930158",

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AU - Jiang, Zhenyu

AU - Hu, Wenjia

AU - Liu, Yan

AU - Zhang, Wenjun

AU - Mo, Chen

AU - You, Guanjun

AU - Wang, Li

AU - Atalla, Mahmoud R.M.

AU - Zhang, Yu

AU - Liu, Jie

AU - Kurhade, Kandhar K.

AU - Xu, Jian

PY - 2015/8/25

Y1 - 2015/8/25

N2 - In an attempt to suppress the dark current, the barrier layer engineer for solution-processed PbSe colloidal quantum-dot (CQD) photodetectors has been investigated in the present study. It was found that the dark current can be significantly suppressed by implementing two types of carrier blocking layers, namely, hole blocking layer and electron blocking layer, sandwiched in between two active PbSe CQD layers. Meanwhile no adverse impact has been observed for the photo current. Our study suggests that this improvement resides on the transport pathway created via carrier recombination at intermediate layer, which provides wide implications for the suppression of dark current for infrared photodetectors.

AB - In an attempt to suppress the dark current, the barrier layer engineer for solution-processed PbSe colloidal quantum-dot (CQD) photodetectors has been investigated in the present study. It was found that the dark current can be significantly suppressed by implementing two types of carrier blocking layers, namely, hole blocking layer and electron blocking layer, sandwiched in between two active PbSe CQD layers. Meanwhile no adverse impact has been observed for the photo current. Our study suggests that this improvement resides on the transport pathway created via carrier recombination at intermediate layer, which provides wide implications for the suppression of dark current for infrared photodetectors.

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Suppression of dark current through barrier engineer for solution-processed colloidal quantum-dots infrared photodetectors

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