Vertical Architecture Solution-Processed Quantum Dot Photodetectors with Amorphous Selenium Hole Transport Layer

Atreyo Mukherjee; Haripriya Kannan; Le Thanh Triet Ho; Zhihang Han; Jann Stavro; Adrian Howansky; Neha Nooman; Kim Kisslinger; Sébastien Léveillé; Orhan Kizilkaya; Xiangyu Liu; Håvard Mølnås; Shlok Joseph Paul; Dong Hyun Sung; Elisa Riedo; Abdul Rumaiz; Dragica Vasileska; Wei Zhao; Ayaskanta Sahu; Amir H. Goldan

doi:10.1021/acsphotonics.2c01353

Vertical Architecture Solution-Processed Quantum Dot Photodetectors with Amorphous Selenium Hole Transport Layer

Atreyo Mukherjee, Haripriya Kannan, Le Thanh Triet Ho, Zhihang Han, Jann Stavro, Adrian Howansky, Neha Nooman, Kim Kisslinger, Sébastien Léveillé, Orhan Kizilkaya, Xiangyu Liu, Håvard Mølnås, Shlok Joseph Paul, Dong Hyun Sung, Elisa Riedo, Abdul Rumaiz, Dragica Vasileska, Wei Zhao, Ayaskanta Sahu, Amir H. Goldan

Engineering, Ira A. Fulton Schools of (IAFSE)

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

2 Scopus citations

Abstract

Colloidal quantum dots (CQDs) provide wide spectral tunability and high absorption coefficients owing to quantum confinement and large oscillator strengths, which along with solution processability, allow a facile, low-cost, and room-temperature deposition technique for the fabrication of photonic devices. However, many solution-processed CQD photodetector devices demonstrate low specific-detectivity and slow temporal response. To achieve improved photodetector characteristics, limiting carrier recombination and enhancing photogenerated carrier separation are crucial. In this study, we develop and present an alternate vertical-stack photodetector wherein we use a solution-processed quantum dot photoconversion layer coupled to an amorphous selenium (a-Se) wide-bandgap charge transport layer that is capable of exhibiting single-carrier hole impact ionization and is compatible with active-matrix readout circuitry. This a-Se chalcogenide transport layer enables the fabrication of high-performance and reliable solution-processed quantum dot photodetectors, with enhanced charge extraction capabilities, high specific detectivity (D* ∼ 0.5-5 × 10¹² Jones), fast 3 dB electrical bandwidth (3 dB BW ∼ 22 MHz), low dark current density (J_D ∼ 5-10 pA/cm²), low noise current (i_n ∼ 20-25 fW/Hz^1/2), and high linear dynamic range (LDR ∼ 130-150 dB) across the measured visible electromagnetic spectrum (∼405-656 nm).

Original language	English (US)
Pages (from-to)	134-146
Number of pages	13
Journal	ACS Photonics
Volume	10
Issue number	1
DOIs	https://doi.org/10.1021/acsphotonics.2c01353
State	Published - Jan 18 2023

Keywords

amorphous hole transport layer
avalanche photodiodes
avalanche transport layer
cadmium selenide quantum dots
colloidal quantum dot photodetectors
vertical-stack photodetectors

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Biotechnology
Atomic and Molecular Physics, and Optics
Electrical and Electronic Engineering

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10.1021/acsphotonics.2c01353

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Mukherjee, A., Kannan, H., Triet Ho, L. T., Han, Z., Stavro, J., Howansky, A., Nooman, N., Kisslinger, K., Léveillé, S., Kizilkaya, O., Liu, X., Mølnås, H., Paul, S. J., Sung, D. H., Riedo, E., Rumaiz, A., Vasileska, D., Zhao, W., Sahu, A., & Goldan, A. H. (2023). Vertical Architecture Solution-Processed Quantum Dot Photodetectors with Amorphous Selenium Hole Transport Layer. ACS Photonics, 10(1), 134-146. https://doi.org/10.1021/acsphotonics.2c01353

Mukherjee, A, Kannan, H, Triet Ho, LT, Han, Z, Stavro, J, Howansky, A, Nooman, N, Kisslinger, K, Léveillé, S, Kizilkaya, O, Liu, X, Mølnås, H, Paul, SJ, Sung, DH, Riedo, E, Rumaiz, A, Vasileska, D, Zhao, W, Sahu, A & Goldan, AH 2023, 'Vertical Architecture Solution-Processed Quantum Dot Photodetectors with Amorphous Selenium Hole Transport Layer', ACS Photonics, vol. 10, no. 1, pp. 134-146. https://doi.org/10.1021/acsphotonics.2c01353

@article{330f82e90c2847818ab22f78215da2e1,

title = "Vertical Architecture Solution-Processed Quantum Dot Photodetectors with Amorphous Selenium Hole Transport Layer",

abstract = "Colloidal quantum dots (CQDs) provide wide spectral tunability and high absorption coefficients owing to quantum confinement and large oscillator strengths, which along with solution processability, allow a facile, low-cost, and room-temperature deposition technique for the fabrication of photonic devices. However, many solution-processed CQD photodetector devices demonstrate low specific-detectivity and slow temporal response. To achieve improved photodetector characteristics, limiting carrier recombination and enhancing photogenerated carrier separation are crucial. In this study, we develop and present an alternate vertical-stack photodetector wherein we use a solution-processed quantum dot photoconversion layer coupled to an amorphous selenium (a-Se) wide-bandgap charge transport layer that is capable of exhibiting single-carrier hole impact ionization and is compatible with active-matrix readout circuitry. This a-Se chalcogenide transport layer enables the fabrication of high-performance and reliable solution-processed quantum dot photodetectors, with enhanced charge extraction capabilities, high specific detectivity (D* ∼ 0.5-5 × 1012 Jones), fast 3 dB electrical bandwidth (3 dB BW ∼ 22 MHz), low dark current density (JD ∼ 5-10 pA/cm2), low noise current (in ∼ 20-25 fW/Hz1/2), and high linear dynamic range (LDR ∼ 130-150 dB) across the measured visible electromagnetic spectrum (∼405-656 nm).",

keywords = "amorphous hole transport layer, avalanche photodiodes, avalanche transport layer, cadmium selenide quantum dots, colloidal quantum dot photodetectors, vertical-stack photodetectors",

author = "Atreyo Mukherjee and Haripriya Kannan and {Triet Ho}, {Le Thanh} and Zhihang Han and Jann Stavro and Adrian Howansky and Neha Nooman and Kim Kisslinger and S{\'e}bastien L{\'e}veill{\'e} and Orhan Kizilkaya and Xiangyu Liu and H{\aa}vard M{\o}ln{\aa}s and Paul, {Shlok Joseph} and Sung, {Dong Hyun} and Elisa Riedo and Abdul Rumaiz and Dragica Vasileska and Wei Zhao and Ayaskanta Sahu and Goldan, {Amir H.}",

note = "Funding Information: The authors acknowledge Research Computing at Arizona State University for providing (HPC, storage, etc.) resources that have contributed to the research results reported in this paper. The author D.V. gratefully acknowledges the academic donation of Silvaco TCAD tools by Silvaco Inc. used in this study. Work by the author H.K. was (partially) supported by the Schlumberger Foundation Faculty for the Future Program. The author(s) would like to acknowledge the Imaging Facility of CUNY Advanced Science Research Center for instrument use and scientific and technical assistance. We thank Prof. Eray Aydil from NYU, Department of Chemical and Biomolecular Engineering, for helping us to conduct photoluminescence measurements in Horiba Scientific Quanta Master and Quanta-ϕ. We gratefully acknowledge financial support from the National Institutes of Health (R21 EB025300). The author A.H.G. acknowledges the financial support from the National Science Foundation (ECCS 2048390). The author D.V. also acknowledges the financial support from the National Science Foundation (ECCS2025490 and ECCS 2048400). We thank the support to the X-ray facility by the National Science Foundation under Award Number CRIF/CHE-0840277 and by the NSF MRSEC Program under Award Numbers DMR-0820341 and DMR-1420073. Kelvin-Probe Force Microscopy work by the authors X.L. and E.R. acknowledge support from the U.S. Department of Energy, Office of Science, Basic Energy Sciences, MSE Division under Award # DE-SC0018924 and U.S. Army Research Office under Award # W911NF2020116. Funding Information: We gratefully acknowledge financial support from the National Institutes of Health (R21 EB025300). The author A.H.G. acknowledges the financial support from the National Science Foundation (ECCS 2048390). The author D.V. also acknowledges the financial support from the National Science Foundation (ECCS2025490 and ECCS 2048400). We thank the support to the X-ray facility by the National Science Foundation under Award Number CRIF/CHE-0840277 and by the NSF MRSEC Program under Award Numbers DMR-0820341 and DMR-1420073. Kelvin-Probe Force Microscopy work by the authors X.L. and E.R. acknowledge support from the U.S. Department of Energy, Office of Science, Basic Energy Sciences, MSE Division under Award # DE-SC0018924 and U.S. Army Research Office under Award # W911NF2020116. Funding Information: The authors acknowledge Research Computing at Arizona State University for providing (HPC, storage, etc.) resources that have contributed to the research results reported in this paper. The author D.V. gratefully acknowledges the academic donation of Silvaco TCAD tools by Silvaco Inc. used in this study. Work by the author H.K. was (partially) supported by the Schlumberger Foundation Faculty for the Future Program. The author(s) would like to acknowledge the Imaging Facility of CUNY Advanced Science Research Center for instrument use and scientific and technical assistance. We thank Prof. Eray Aydil from NYU, Department of Chemical and Biomolecular Engineering, for helping us to conduct photoluminescence measurements in Horiba Scientific Quanta Master and Quanta-ϕ. Publisher Copyright: {\textcopyright} 2022 American Chemical Society.",

year = "2023",

month = jan,

day = "18",

doi = "10.1021/acsphotonics.2c01353",

language = "English (US)",

volume = "10",

pages = "134--146",

journal = "ACS Photonics",

issn = "2330-4022",

publisher = "American Chemical Society",

number = "1",

}

TY - JOUR

T1 - Vertical Architecture Solution-Processed Quantum Dot Photodetectors with Amorphous Selenium Hole Transport Layer

AU - Mukherjee, Atreyo

AU - Kannan, Haripriya

AU - Triet Ho, Le Thanh

AU - Han, Zhihang

AU - Stavro, Jann

AU - Howansky, Adrian

AU - Nooman, Neha

AU - Kisslinger, Kim

AU - Léveillé, Sébastien

AU - Kizilkaya, Orhan

AU - Liu, Xiangyu

AU - Mølnås, Håvard

AU - Paul, Shlok Joseph

AU - Sung, Dong Hyun

AU - Riedo, Elisa

AU - Rumaiz, Abdul

AU - Vasileska, Dragica

AU - Zhao, Wei

AU - Sahu, Ayaskanta

AU - Goldan, Amir H.

N1 - Funding Information: The authors acknowledge Research Computing at Arizona State University for providing (HPC, storage, etc.) resources that have contributed to the research results reported in this paper. The author D.V. gratefully acknowledges the academic donation of Silvaco TCAD tools by Silvaco Inc. used in this study. Work by the author H.K. was (partially) supported by the Schlumberger Foundation Faculty for the Future Program. The author(s) would like to acknowledge the Imaging Facility of CUNY Advanced Science Research Center for instrument use and scientific and technical assistance. We thank Prof. Eray Aydil from NYU, Department of Chemical and Biomolecular Engineering, for helping us to conduct photoluminescence measurements in Horiba Scientific Quanta Master and Quanta-ϕ. We gratefully acknowledge financial support from the National Institutes of Health (R21 EB025300). The author A.H.G. acknowledges the financial support from the National Science Foundation (ECCS 2048390). The author D.V. also acknowledges the financial support from the National Science Foundation (ECCS2025490 and ECCS 2048400). We thank the support to the X-ray facility by the National Science Foundation under Award Number CRIF/CHE-0840277 and by the NSF MRSEC Program under Award Numbers DMR-0820341 and DMR-1420073. Kelvin-Probe Force Microscopy work by the authors X.L. and E.R. acknowledge support from the U.S. Department of Energy, Office of Science, Basic Energy Sciences, MSE Division under Award # DE-SC0018924 and U.S. Army Research Office under Award # W911NF2020116. Funding Information: We gratefully acknowledge financial support from the National Institutes of Health (R21 EB025300). The author A.H.G. acknowledges the financial support from the National Science Foundation (ECCS 2048390). The author D.V. also acknowledges the financial support from the National Science Foundation (ECCS2025490 and ECCS 2048400). We thank the support to the X-ray facility by the National Science Foundation under Award Number CRIF/CHE-0840277 and by the NSF MRSEC Program under Award Numbers DMR-0820341 and DMR-1420073. Kelvin-Probe Force Microscopy work by the authors X.L. and E.R. acknowledge support from the U.S. Department of Energy, Office of Science, Basic Energy Sciences, MSE Division under Award # DE-SC0018924 and U.S. Army Research Office under Award # W911NF2020116. Funding Information: The authors acknowledge Research Computing at Arizona State University for providing (HPC, storage, etc.) resources that have contributed to the research results reported in this paper. The author D.V. gratefully acknowledges the academic donation of Silvaco TCAD tools by Silvaco Inc. used in this study. Work by the author H.K. was (partially) supported by the Schlumberger Foundation Faculty for the Future Program. The author(s) would like to acknowledge the Imaging Facility of CUNY Advanced Science Research Center for instrument use and scientific and technical assistance. We thank Prof. Eray Aydil from NYU, Department of Chemical and Biomolecular Engineering, for helping us to conduct photoluminescence measurements in Horiba Scientific Quanta Master and Quanta-ϕ. Publisher Copyright: © 2022 American Chemical Society.

PY - 2023/1/18

Y1 - 2023/1/18

N2 - Colloidal quantum dots (CQDs) provide wide spectral tunability and high absorption coefficients owing to quantum confinement and large oscillator strengths, which along with solution processability, allow a facile, low-cost, and room-temperature deposition technique for the fabrication of photonic devices. However, many solution-processed CQD photodetector devices demonstrate low specific-detectivity and slow temporal response. To achieve improved photodetector characteristics, limiting carrier recombination and enhancing photogenerated carrier separation are crucial. In this study, we develop and present an alternate vertical-stack photodetector wherein we use a solution-processed quantum dot photoconversion layer coupled to an amorphous selenium (a-Se) wide-bandgap charge transport layer that is capable of exhibiting single-carrier hole impact ionization and is compatible with active-matrix readout circuitry. This a-Se chalcogenide transport layer enables the fabrication of high-performance and reliable solution-processed quantum dot photodetectors, with enhanced charge extraction capabilities, high specific detectivity (D* ∼ 0.5-5 × 1012 Jones), fast 3 dB electrical bandwidth (3 dB BW ∼ 22 MHz), low dark current density (JD ∼ 5-10 pA/cm2), low noise current (in ∼ 20-25 fW/Hz1/2), and high linear dynamic range (LDR ∼ 130-150 dB) across the measured visible electromagnetic spectrum (∼405-656 nm).

AB - Colloidal quantum dots (CQDs) provide wide spectral tunability and high absorption coefficients owing to quantum confinement and large oscillator strengths, which along with solution processability, allow a facile, low-cost, and room-temperature deposition technique for the fabrication of photonic devices. However, many solution-processed CQD photodetector devices demonstrate low specific-detectivity and slow temporal response. To achieve improved photodetector characteristics, limiting carrier recombination and enhancing photogenerated carrier separation are crucial. In this study, we develop and present an alternate vertical-stack photodetector wherein we use a solution-processed quantum dot photoconversion layer coupled to an amorphous selenium (a-Se) wide-bandgap charge transport layer that is capable of exhibiting single-carrier hole impact ionization and is compatible with active-matrix readout circuitry. This a-Se chalcogenide transport layer enables the fabrication of high-performance and reliable solution-processed quantum dot photodetectors, with enhanced charge extraction capabilities, high specific detectivity (D* ∼ 0.5-5 × 1012 Jones), fast 3 dB electrical bandwidth (3 dB BW ∼ 22 MHz), low dark current density (JD ∼ 5-10 pA/cm2), low noise current (in ∼ 20-25 fW/Hz1/2), and high linear dynamic range (LDR ∼ 130-150 dB) across the measured visible electromagnetic spectrum (∼405-656 nm).

KW - amorphous hole transport layer

KW - avalanche photodiodes

KW - avalanche transport layer

KW - cadmium selenide quantum dots

KW - colloidal quantum dot photodetectors

KW - vertical-stack photodetectors

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U2 - 10.1021/acsphotonics.2c01353

DO - 10.1021/acsphotonics.2c01353

M3 - Article

AN - SCOPUS:85145576228

SN - 2330-4022

VL - 10

SP - 134

EP - 146

JO - ACS Photonics

JF - ACS Photonics

IS - 1

ER -

Vertical Architecture Solution-Processed Quantum Dot Photodetectors with Amorphous Selenium Hole Transport Layer

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