High Temperature Resistant Solar‐Blind Ultraviolet Photosensor for Neuromorphic Computing and Cryptography

High‐temperature resistant solar‐blind optoelectronic synapse has a significant demand such as aerospace and fire warning, which integrates sensing and processing functions to realize complex functions like learning, recognition, and memory. However, developing such device remains a tremendous chall...

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Bibliographic Details
Published in:Advanced functional materials 2024-06, Vol.34 (24), p.n/a
Main Authors: Chen, Yancheng, Li, Ying, Niu, Shifeng, Yang, Xun, Dou, Wenjie, Shan, Chongxin, Shen, Guozhen
Format: Article
Language:English
Subjects:
Artificial neural networks
Cryptography
Ga2O3
Gallium oxides
Handwriting recognition
High temperature
high‐temperature resistant
Luminous intensity
Neuromorphic computing
Optoelectronics
solar‐blind photosynapse
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Summary:High‐temperature resistant solar‐blind optoelectronic synapse has a significant demand such as aerospace and fire warning, which integrates sensing and processing functions to realize complex functions like learning, recognition, and memory. However, developing such device remains a tremendous challenge. Herein, a two‐terminal GaOX solar‐blind optoelectronic synapse with high‐temperature working ability is proposed, and it is applied to neuromorphic computing and cryptography. Benefiting from the high internal gain, the device can detect the light intensity of nW cm−2, displaying one of the best figures‐of‐merit in solar‐blind photodetectors. Furthermore, the device possesses remarkable image sensing and memorization ability because of its ultrasensitive light detection ability and prominent synapse performance resulting from large charge trapping states density. Simultaneously, the device shows undamped photodetection and synaptic performances even at 610 K, reflecting a high‐temperature endurance and a desired property for practical applications under harsh environment. Moreover, by constructing an artificial neural network, high‐precision recognition of handwritten digits are realized under 610 K. A photosynaptic array with 12 × 12 pixels is constructed, and it is applied in cryptography that enables simultaneous sensing and encryption in the same devices. This work is expected to drive the progress of Ga2O3 in harsh environment. A two‐terminal GaOX solar‐blind photosynapse with high‐temperature working ability is demonstrated, and it is applied to neuromorphic computing and cryptography. The device can detect light intensity as low as nW cm−2, and show good synaptic performance even at 610 K. These results are expected to accelerate the research process of photosynapses that can resist harsh‐environment.
ISSN:1616-301X
1616-3028
DOI:10.1002/adfm.202315383