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Intrinsic Defect‐Driven Synergistic Synaptic Heterostructures for Gate‐Free Neuromorphic Phototransistors. / Deng, Yao; Liu, Shenghong; Ma, Xiaoxi; Guo, Shuyang; Zhai, Baoxing; Zhang, Zihan; Li, Manshi; Yu, Yimeng; Hu, Wenhua; Yang, Hui; Kapitonov, Yury; Han, Junbo; Wu, Jinsong; Li, Yuan; Zhai, Tianyou.

в: Advanced Materials, Том 36, № 19, 2309940, 09.05.2024.

Результаты исследований: Научные публикации в периодических изданияхстатьяРецензирование

Harvard

Deng, Y, Liu, S, Ma, X, Guo, S, Zhai, B, Zhang, Z, Li, M, Yu, Y, Hu, W, Yang, H, Kapitonov, Y, Han, J, Wu, J, Li, Y & Zhai, T 2024, 'Intrinsic Defect‐Driven Synergistic Synaptic Heterostructures for Gate‐Free Neuromorphic Phototransistors', Advanced Materials, Том. 36, № 19, 2309940. https://doi.org/10.1002/adma.202309940, https://doi.org/10.1002/adma.202309940

APA

Deng, Y., Liu, S., Ma, X., Guo, S., Zhai, B., Zhang, Z., Li, M., Yu, Y., Hu, W., Yang, H., Kapitonov, Y., Han, J., Wu, J., Li, Y., & Zhai, T. (2024). Intrinsic Defect‐Driven Synergistic Synaptic Heterostructures for Gate‐Free Neuromorphic Phototransistors. Advanced Materials, 36(19), [2309940]. https://doi.org/10.1002/adma.202309940, https://doi.org/10.1002/adma.202309940

Vancouver

Deng Y, Liu S, Ma X, Guo S, Zhai B, Zhang Z и пр. Intrinsic Defect‐Driven Synergistic Synaptic Heterostructures for Gate‐Free Neuromorphic Phototransistors. Advanced Materials. 2024 Май 9;36(19). 2309940. https://doi.org/10.1002/adma.202309940, https://doi.org/10.1002/adma.202309940

Author

Deng, Yao ; Liu, Shenghong ; Ma, Xiaoxi ; Guo, Shuyang ; Zhai, Baoxing ; Zhang, Zihan ; Li, Manshi ; Yu, Yimeng ; Hu, Wenhua ; Yang, Hui ; Kapitonov, Yury ; Han, Junbo ; Wu, Jinsong ; Li, Yuan ; Zhai, Tianyou. / Intrinsic Defect‐Driven Synergistic Synaptic Heterostructures for Gate‐Free Neuromorphic Phototransistors. в: Advanced Materials. 2024 ; Том 36, № 19.

BibTeX

@article{c50bd56abf38471d8ab95ed94f908b13,
title = "Intrinsic Defect‐Driven Synergistic Synaptic Heterostructures for Gate‐Free Neuromorphic Phototransistors",
abstract = "The optoelectronic synaptic devices based on two-dimensional (2D) materials offer great advances for future neuromorphic visual systems with dramatically improved integration density and power efficiency. The effective charge capture and retention are considered as one vital prerequisite to realizing the synaptic memory function. However, the current 2D synaptic devices are predominantly relied on materials with artificially-engineered defects or intricate gate-controlled architectures to realize the charge trapping process. These approaches, unfortunately, suffer from the degradation of pristine materials, rapid device failure, and unnecessary complication of device structures. To address these challenges, an innovative gate-free heterostructure paradigm is introduced herein. The heterostructure presents a distinctive dome-like morphology wherein a defect-rich Fe7S8 core is enveloped snugly by a curved MoS2 dome shell (Fe7S8@MoS2), allowing the realization of effective photocarrier trapping through the intrinsic defects in the adjacent Fe7S8 core. The resultant neuromorphic devices exhibit remarkable light-tunable synaptic behaviors with memory time up to ≈800 s under single optical pulse, thus demonstrating great advances in simulating visual recognition system with significantly improved image recognition efficiency. The emergence of such heterostructures foreshadows a promising trajectory for underpinning future synaptic devices, catalyzing the realization of high-efficiency and intricate visual processing applications.",
keywords = "2D materials, chemical vapor deposition, heterostructure, image recognition, optoelectronic synapse",
author = "Yao Deng and Shenghong Liu and Xiaoxi Ma and Shuyang Guo and Baoxing Zhai and Zihan Zhang and Manshi Li and Yimeng Yu and Wenhua Hu and Hui Yang and Yury Kapitonov and Junbo Han and Jinsong Wu and Yuan Li and Tianyou Zhai",
year = "2024",
month = may,
day = "9",
doi = "10.1002/adma.202309940",
language = "English",
volume = "36",
journal = "Advanced Materials",
issn = "0935-9648",
publisher = "Wiley-Blackwell",
number = "19",

}

RIS

TY - JOUR

T1 - Intrinsic Defect‐Driven Synergistic Synaptic Heterostructures for Gate‐Free Neuromorphic Phototransistors

AU - Deng, Yao

AU - Liu, Shenghong

AU - Ma, Xiaoxi

AU - Guo, Shuyang

AU - Zhai, Baoxing

AU - Zhang, Zihan

AU - Li, Manshi

AU - Yu, Yimeng

AU - Hu, Wenhua

AU - Yang, Hui

AU - Kapitonov, Yury

AU - Han, Junbo

AU - Wu, Jinsong

AU - Li, Yuan

AU - Zhai, Tianyou

PY - 2024/5/9

Y1 - 2024/5/9

N2 - The optoelectronic synaptic devices based on two-dimensional (2D) materials offer great advances for future neuromorphic visual systems with dramatically improved integration density and power efficiency. The effective charge capture and retention are considered as one vital prerequisite to realizing the synaptic memory function. However, the current 2D synaptic devices are predominantly relied on materials with artificially-engineered defects or intricate gate-controlled architectures to realize the charge trapping process. These approaches, unfortunately, suffer from the degradation of pristine materials, rapid device failure, and unnecessary complication of device structures. To address these challenges, an innovative gate-free heterostructure paradigm is introduced herein. The heterostructure presents a distinctive dome-like morphology wherein a defect-rich Fe7S8 core is enveloped snugly by a curved MoS2 dome shell (Fe7S8@MoS2), allowing the realization of effective photocarrier trapping through the intrinsic defects in the adjacent Fe7S8 core. The resultant neuromorphic devices exhibit remarkable light-tunable synaptic behaviors with memory time up to ≈800 s under single optical pulse, thus demonstrating great advances in simulating visual recognition system with significantly improved image recognition efficiency. The emergence of such heterostructures foreshadows a promising trajectory for underpinning future synaptic devices, catalyzing the realization of high-efficiency and intricate visual processing applications.

AB - The optoelectronic synaptic devices based on two-dimensional (2D) materials offer great advances for future neuromorphic visual systems with dramatically improved integration density and power efficiency. The effective charge capture and retention are considered as one vital prerequisite to realizing the synaptic memory function. However, the current 2D synaptic devices are predominantly relied on materials with artificially-engineered defects or intricate gate-controlled architectures to realize the charge trapping process. These approaches, unfortunately, suffer from the degradation of pristine materials, rapid device failure, and unnecessary complication of device structures. To address these challenges, an innovative gate-free heterostructure paradigm is introduced herein. The heterostructure presents a distinctive dome-like morphology wherein a defect-rich Fe7S8 core is enveloped snugly by a curved MoS2 dome shell (Fe7S8@MoS2), allowing the realization of effective photocarrier trapping through the intrinsic defects in the adjacent Fe7S8 core. The resultant neuromorphic devices exhibit remarkable light-tunable synaptic behaviors with memory time up to ≈800 s under single optical pulse, thus demonstrating great advances in simulating visual recognition system with significantly improved image recognition efficiency. The emergence of such heterostructures foreshadows a promising trajectory for underpinning future synaptic devices, catalyzing the realization of high-efficiency and intricate visual processing applications.

KW - 2D materials

KW - chemical vapor deposition

KW - heterostructure

KW - image recognition

KW - optoelectronic synapse

UR - https://www.mendeley.com/catalogue/94bf1cd1-1a6a-3033-9cc7-29da4f407c3a/

U2 - 10.1002/adma.202309940

DO - 10.1002/adma.202309940

M3 - Article

VL - 36

JO - Advanced Materials

JF - Advanced Materials

SN - 0935-9648

IS - 19

M1 - 2309940

ER -

ID: 119249251