Ferroelectric Quantum Dots for Retinomorphic In-Sensor Computing

Tingyu Long; Huanyu Zhou; Jaewan Ko; Hongwei Tan; Jaemin Lim; Yanfei Zhao; Daehan Kang; Eojin Yoon; Gyeong Tak Go; Somin Kim; Seung Woo Lee; Chan Yul Park; Hyojun Choi; Hyeran Kim; Hyung Joong Yun; Sung Hyuk Park; Kwan Sik Park; Jeong Woo Park; Mungeun Kim; Yong Soo Cho; Ho Won Jang; Wenqiang Yang; Min Hyuk Park; Wan Ki Bae; Sebastiaan van Dijken; Joona Bang; Tae Woo Lee

doi:10.1002/adma.202504117

Ferroelectric Quantum Dots for Retinomorphic In-Sensor Computing

Tingyu Long
, Huanyu Zhou
, Jaewan Ko
, Hongwei Tan
, Jaemin Lim
, Yanfei Zhao
, Daehan Kang
, Eojin Yoon
, Gyeong Tak Go
, Somin Kim
, Seung Woo Lee
, Chan Yul Park
, Hyojun Choi
, Hyeran Kim
, Hyung Joong Yun
, Sung Hyuk Park
, Kwan Sik Park
, Jeong Woo Park
, Mungeun Kim
, Yong Soo Cho

Ho Won Jang, Wenqiang Yang, Min Hyuk Park, Wan Ki Bae, Sebastiaan van Dijken, Joona Bang^*, Tae Woo Lee^*

^*Corresponding author for this work

Seoul National University
Korea University
Sungkyunkwan University
Korea Basic Science Institute
Yonsei University
Beihang University

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

4 Citations (Web of Science)

2 Downloads (Pure)

Abstract

Quantum dots (QDs) offer significant potential for neuromorphic machine vision, owing to their high absorption coefficients, and to absorption that spans the ultraviolet-to-visible range. However, their practical application faces critical challenges in achieving accurate target recognition and tracking in low-light and dynamically-changing environments. A fundamental limitation is a result of the exciton-confinement effect of QDs, which impedes efficient exciton dissociation. To overcome this problem, we synthesized ferroelectric QDs (FE-QDs) that are functionalized with thiol-terminated polyvinylidene fluoride (PVDF-SH) ligands, and empolyed them as the photo-sensitive floating gate in an organic synaptic transistor. When a polarization voltage is applied to the organic synaptic transistors, the FE-QD film generates an electric field that counteracts exciton confinement. The process substantially facilitates exciton dissociation in QDs, and regulates charge accumulation in the channel layer. Integrated with machine learning algorithms, the QD-based device achieved 100% accuracy in detecting simulated car motion in low-light environments, highlighting the potential of adaptive, dynamic sensing technologies for applications in night vision, autonomous driving, and intelligent transportation systems.

Original language	English
Article number	e04117
Pages (from-to)	1-13
Number of pages	13
Journal	Advanced Materials
DOIs	https://doi.org/10.1002/adma.202504117
Publication status	E-pub ahead of print - 25 Aug 2025
MoE publication type	A1 Journal article-refereed

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This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 11 Sustainable Cities and Communities

Keywords

dynamic vision perception
ferroelectric ligand
ferroelectric-controlled photoresponse
molecular design
quantum dot
scotopic adaptation

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10.1002/adma.202504117Licence: CC BY

Ferroelectric_Quantum_Dots_for_Retinomorphic_In-Sensor_ComputingFinal published version, 4.57 MBLicence: CC BY

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Long, T., Zhou, H., Ko, J., Tan, H., Lim, J., Zhao, Y., Kang, D., Yoon, E., Go, G. T., Kim, S., Lee, S. W., Park, C. Y., Choi, H., Kim, H., Yun, H. J., Park, S. H., Park, K. S., Park, J. W., Kim, M., ... Lee, T. W. (2025). Ferroelectric Quantum Dots for Retinomorphic In-Sensor Computing. Advanced Materials, 1-13. Article e04117. Advance online publication. https://doi.org/10.1002/adma.202504117

@article{d9dc73658c4a49ff94175dc45b1f4e73,

title = "Ferroelectric Quantum Dots for Retinomorphic In-Sensor Computing",

abstract = "Quantum dots (QDs) offer significant potential for neuromorphic machine vision, owing to their high absorption coefficients, and to absorption that spans the ultraviolet-to-visible range. However, their practical application faces critical challenges in achieving accurate target recognition and tracking in low-light and dynamically-changing environments. A fundamental limitation is a result of the exciton-confinement effect of QDs, which impedes efficient exciton dissociation. To overcome this problem, we synthesized ferroelectric QDs (FE-QDs) that are functionalized with thiol-terminated polyvinylidene fluoride (PVDF-SH) ligands, and empolyed them as the photo-sensitive floating gate in an organic synaptic transistor. When a polarization voltage is applied to the organic synaptic transistors, the FE-QD film generates an electric field that counteracts exciton confinement. The process substantially facilitates exciton dissociation in QDs, and regulates charge accumulation in the channel layer. Integrated with machine learning algorithms, the QD-based device achieved 100\% accuracy in detecting simulated car motion in low-light environments, highlighting the potential of adaptive, dynamic sensing technologies for applications in night vision, autonomous driving, and intelligent transportation systems.",

keywords = "dynamic vision perception, ferroelectric ligand, ferroelectric-controlled photoresponse, molecular design, quantum dot, scotopic adaptation",

author = "Tingyu Long and Huanyu Zhou and Jaewan Ko and Hongwei Tan and Jaemin Lim and Yanfei Zhao and Daehan Kang and Eojin Yoon and Go, \{Gyeong Tak\} and Somin Kim and Lee, \{Seung Woo\} and Park, \{Chan Yul\} and Hyojun Choi and Hyeran Kim and Yun, \{Hyung Joong\} and Park, \{Sung Hyuk\} and Park, \{Kwan Sik\} and Park, \{Jeong Woo\} and Mungeun Kim and Cho, \{Yong Soo\} and Jang, \{Ho Won\} and Wenqiang Yang and Park, \{Min Hyuk\} and Bae, \{Wan Ki\} and \{van Dijken\}, Sebastiaan and Joona Bang and Lee, \{Tae Woo\}",

note = "Publisher Copyright: {\textcopyright} 2025 The Author(s). Advanced Materials published by Wiley-VCH GmbH.",

year = "2025",

month = aug,

day = "25",

doi = "10.1002/adma.202504117",

language = "English",

pages = "1--13",

journal = "Advanced Materials",

issn = "0935-9648",

publisher = "Wiley",

}

Long, T, Zhou, H, Ko, J, Tan, H, Lim, J, Zhao, Y, Kang, D, Yoon, E, Go, GT, Kim, S, Lee, SW, Park, CY, Choi, H, Kim, H, Yun, HJ, Park, SH, Park, KS, Park, JW, Kim, M, Cho, YS, Jang, HW, Yang, W, Park, MH, Bae, WK, van Dijken, S, Bang, J & Lee, TW 2025, 'Ferroelectric Quantum Dots for Retinomorphic In-Sensor Computing', Advanced Materials, pp. 1-13. https://doi.org/10.1002/adma.202504117

TY - JOUR

T1 - Ferroelectric Quantum Dots for Retinomorphic In-Sensor Computing

AU - Long, Tingyu

AU - Zhou, Huanyu

AU - Ko, Jaewan

AU - Tan, Hongwei

AU - Lim, Jaemin

AU - Zhao, Yanfei

AU - Kang, Daehan

AU - Yoon, Eojin

AU - Go, Gyeong Tak

AU - Kim, Somin

AU - Lee, Seung Woo

AU - Park, Chan Yul

AU - Choi, Hyojun

AU - Kim, Hyeran

AU - Yun, Hyung Joong

AU - Park, Sung Hyuk

AU - Park, Kwan Sik

AU - Park, Jeong Woo

AU - Kim, Mungeun

AU - Cho, Yong Soo

AU - Jang, Ho Won

AU - Yang, Wenqiang

AU - Park, Min Hyuk

AU - Bae, Wan Ki

AU - van Dijken, Sebastiaan

AU - Bang, Joona

AU - Lee, Tae Woo

PY - 2025/8/25

Y1 - 2025/8/25

N2 - Quantum dots (QDs) offer significant potential for neuromorphic machine vision, owing to their high absorption coefficients, and to absorption that spans the ultraviolet-to-visible range. However, their practical application faces critical challenges in achieving accurate target recognition and tracking in low-light and dynamically-changing environments. A fundamental limitation is a result of the exciton-confinement effect of QDs, which impedes efficient exciton dissociation. To overcome this problem, we synthesized ferroelectric QDs (FE-QDs) that are functionalized with thiol-terminated polyvinylidene fluoride (PVDF-SH) ligands, and empolyed them as the photo-sensitive floating gate in an organic synaptic transistor. When a polarization voltage is applied to the organic synaptic transistors, the FE-QD film generates an electric field that counteracts exciton confinement. The process substantially facilitates exciton dissociation in QDs, and regulates charge accumulation in the channel layer. Integrated with machine learning algorithms, the QD-based device achieved 100% accuracy in detecting simulated car motion in low-light environments, highlighting the potential of adaptive, dynamic sensing technologies for applications in night vision, autonomous driving, and intelligent transportation systems.

AB - Quantum dots (QDs) offer significant potential for neuromorphic machine vision, owing to their high absorption coefficients, and to absorption that spans the ultraviolet-to-visible range. However, their practical application faces critical challenges in achieving accurate target recognition and tracking in low-light and dynamically-changing environments. A fundamental limitation is a result of the exciton-confinement effect of QDs, which impedes efficient exciton dissociation. To overcome this problem, we synthesized ferroelectric QDs (FE-QDs) that are functionalized with thiol-terminated polyvinylidene fluoride (PVDF-SH) ligands, and empolyed them as the photo-sensitive floating gate in an organic synaptic transistor. When a polarization voltage is applied to the organic synaptic transistors, the FE-QD film generates an electric field that counteracts exciton confinement. The process substantially facilitates exciton dissociation in QDs, and regulates charge accumulation in the channel layer. Integrated with machine learning algorithms, the QD-based device achieved 100% accuracy in detecting simulated car motion in low-light environments, highlighting the potential of adaptive, dynamic sensing technologies for applications in night vision, autonomous driving, and intelligent transportation systems.

KW - dynamic vision perception

KW - ferroelectric ligand

KW - ferroelectric-controlled photoresponse

KW - molecular design

KW - quantum dot

KW - scotopic adaptation

UR - https://www.scopus.com/pages/publications/105013869916

U2 - 10.1002/adma.202504117

DO - 10.1002/adma.202504117

M3 - Article

AN - SCOPUS:105013869916

SN - 0935-9648

SP - 1

EP - 13

JO - Advanced Materials

JF - Advanced Materials

M1 - e04117

ER -

Ferroelectric Quantum Dots for Retinomorphic In-Sensor Computing

Abstract

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Keywords

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