Carrier-capture-assisted optoelectronics based on van der Waals materials to imitate medicine-acting metaplasticity

Qianfan Nie; Caifang Gao; Feng Shou Yang; Ko Chun Lee; Che Yi Lin; Xiang Wang; Ching Hwa Ho; Chen Hsin Lien; Shu Ping Lin; Mengjiao Li; Yen Fu Lin; Wenwu Li; Zhigao Hu; Junhao Chu

doi:10.1038/s41699-021-00241-0

Carrier-capture-assisted optoelectronics based on van der Waals materials to imitate medicine-acting metaplasticity

Qianfan Nie
, Caifang Gao
, Feng Shou Yang
, Ko Chun Lee
, Che Yi Lin
, Xiang Wang
, Ching Hwa Ho
, Chen Hsin Lien
, Shu Ping Lin
, Mengjiao Li^*
, Yen Fu Lin^*
, Wenwu Li^*
, Zhigao Hu
, Junhao Chu

^*此作品的通讯作者

物理与电子科学学院

East China Normal University
Fudan University
National Chung Hsing University
National Tsing Hua University
National Taiwan University of Science and Technology

科研成果: 期刊稿件 › 文章 › 同行评审

14 引用（Scopus）

摘要

Recently, researchers have focused on optoelectronics based on two-dimensional van der Waals materials to realize multifunctional memory and neuron applications. Layered indium selenide (InSe) semiconductors satisfy various requirements as photosensitive channel materials, and enable the realization of intriguing optoelectronic applications. Herein, we demonstrate InSe photonic devices with different trends of output currents rooted in the carrier capture/release events under various gate voltages. Furthermore, we reported an increasing/flattening/decreasing synaptic weight change index (∆W_n) via a modulated gate electric field, which we use to imitate medicine-acting metaplasticity with effective/stable/ineffective features analogous to the synaptic weight change in the nervous system of the human brain. Finally, we take advantage of the low-frequency noise (LFN) measurements and the energy-band explanation to verify the rationality of carrier capture-assisted optoelectronics applied to neural simulation at the device level. Utilizing optoelectronics to simulate essential biomedical neurobehaviors, we experimentally demonstrate the feasibility and meaningfulness of combining electronic engineering with biomedical neurology.

源语言	英语
文章编号	60
期刊	npj 2D Materials and Applications
卷	5
期	1
DOI	https://doi.org/10.1038/s41699-021-00241-0
出版状态	已出版 - 12月 2021

联合国可持续发展目标

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可持续发展目标 3 良好健康与福祉

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title = "Carrier-capture-assisted optoelectronics based on van der Waals materials to imitate medicine-acting metaplasticity",

abstract = "Recently, researchers have focused on optoelectronics based on two-dimensional van der Waals materials to realize multifunctional memory and neuron applications. Layered indium selenide (InSe) semiconductors satisfy various requirements as photosensitive channel materials, and enable the realization of intriguing optoelectronic applications. Herein, we demonstrate InSe photonic devices with different trends of output currents rooted in the carrier capture/release events under various gate voltages. Furthermore, we reported an increasing/flattening/decreasing synaptic weight change index (∆Wn) via a modulated gate electric field, which we use to imitate medicine-acting metaplasticity with effective/stable/ineffective features analogous to the synaptic weight change in the nervous system of the human brain. Finally, we take advantage of the low-frequency noise (LFN) measurements and the energy-band explanation to verify the rationality of carrier capture-assisted optoelectronics applied to neural simulation at the device level. Utilizing optoelectronics to simulate essential biomedical neurobehaviors, we experimentally demonstrate the feasibility and meaningfulness of combining electronic engineering with biomedical neurology.",

author = "Qianfan Nie and Caifang Gao and Yang, \{Feng Shou\} and Lee, \{Ko Chun\} and Lin, \{Che Yi\} and Xiang Wang and Ho, \{Ching Hwa\} and Lien, \{Chen Hsin\} and Lin, \{Shu Ping\} and Mengjiao Li and Lin, \{Yen Fu\} and Wenwu Li and Zhigao Hu and Junhao Chu",

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doi = "10.1038/s41699-021-00241-0",

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T1 - Carrier-capture-assisted optoelectronics based on van der Waals materials to imitate medicine-acting metaplasticity

AU - Nie, Qianfan

AU - Gao, Caifang

AU - Yang, Feng Shou

AU - Lee, Ko Chun

AU - Lin, Che Yi

AU - Wang, Xiang

AU - Ho, Ching Hwa

AU - Lien, Chen Hsin

AU - Lin, Shu Ping

AU - Li, Mengjiao

AU - Lin, Yen Fu

AU - Li, Wenwu

AU - Hu, Zhigao

AU - Chu, Junhao

PY - 2021/12

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N2 - Recently, researchers have focused on optoelectronics based on two-dimensional van der Waals materials to realize multifunctional memory and neuron applications. Layered indium selenide (InSe) semiconductors satisfy various requirements as photosensitive channel materials, and enable the realization of intriguing optoelectronic applications. Herein, we demonstrate InSe photonic devices with different trends of output currents rooted in the carrier capture/release events under various gate voltages. Furthermore, we reported an increasing/flattening/decreasing synaptic weight change index (∆Wn) via a modulated gate electric field, which we use to imitate medicine-acting metaplasticity with effective/stable/ineffective features analogous to the synaptic weight change in the nervous system of the human brain. Finally, we take advantage of the low-frequency noise (LFN) measurements and the energy-band explanation to verify the rationality of carrier capture-assisted optoelectronics applied to neural simulation at the device level. Utilizing optoelectronics to simulate essential biomedical neurobehaviors, we experimentally demonstrate the feasibility and meaningfulness of combining electronic engineering with biomedical neurology.

AB - Recently, researchers have focused on optoelectronics based on two-dimensional van der Waals materials to realize multifunctional memory and neuron applications. Layered indium selenide (InSe) semiconductors satisfy various requirements as photosensitive channel materials, and enable the realization of intriguing optoelectronic applications. Herein, we demonstrate InSe photonic devices with different trends of output currents rooted in the carrier capture/release events under various gate voltages. Furthermore, we reported an increasing/flattening/decreasing synaptic weight change index (∆Wn) via a modulated gate electric field, which we use to imitate medicine-acting metaplasticity with effective/stable/ineffective features analogous to the synaptic weight change in the nervous system of the human brain. Finally, we take advantage of the low-frequency noise (LFN) measurements and the energy-band explanation to verify the rationality of carrier capture-assisted optoelectronics applied to neural simulation at the device level. Utilizing optoelectronics to simulate essential biomedical neurobehaviors, we experimentally demonstrate the feasibility and meaningfulness of combining electronic engineering with biomedical neurology.

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Carrier-capture-assisted optoelectronics based on van der Waals materials to imitate medicine-acting metaplasticity

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