High‐Contrast Bidirectional Optoelectronic Synapses based on 2D Molecular Crystal Heterojunctions for Motion Detection

Zhu, Xiaoting; Gao, Changsong; Ren, Yiwen; Zhang, Xianghong; Li, Enlong; Wang, Congyong; Yang, Fangxu; Wu, Jishan; Hu, Wenping; Chen, Huipeng

doi:10.1002/adma.202301468

Cited by 20 publications

(14 citation statements)

References 70 publications

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“…The training process is a gradual learning process and it can also be presented by confusing the colors of the diagonals in the matrix. 48 When the maximum inferred output value of each row gradually agrees with the desired output value of each column, it indicates that successful recognition of the digits is achieved. As shown in Figure S9a-i, Supporting Information, the recognition accuracy increases as the number of training epoch increases.…”

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confidence: 89%

“…As shown in Figure h, it can be found that the recognition rate under DUV light stimulation is the largest at 94% after 20 training epochs. The training process is a gradual learning process and it can also be presented by confusing the colors of the diagonals in the matrix . When the maximum inferred output value of each row gradually agrees with the desired output value of each column, it indicates that successful recognition of the digits is achieved.…”

mentioning

confidence: 99%

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Flexible Optoelectronic Synapses Based on Conjugated Polymer Blends for Ultra Broadband Spectrum Light Perception

Jiang,

Yang,

Yuan

et al. 2024

ACS Materials Lett.

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We demonstrate a flexible optoelectronic synaptic device that uses a donor−acceptor conjugated polymer with excellent electrical properties and a highly optically active block copolymer to form a heterojunction as the active layer, enabling ultrabroad-spectrum perception from deep ultraviolet (DUV), to visible (vis), and to near-infrared (NIR) for the first time. Essential synaptic behaviors have been successfully simulated, such as learning experience behavior simulation, international Morse code communication, and high-pass filtering. The synaptic device shows stable synaptic properties when bent at different radii of curvature and at different numbers of bending cycles. When the device is extremely deformed under a radius of curvature of 4 mm, the postsynaptic current is still maintained above 84%. Moreover, an artificial reflex arc was constructed using the flexible optoelectronic synapse as a key information processing unit. Recognition of digits was achieved by constructing an artificial neural network under DUV light stimulation, achieving the highest recognition rate so far, up to 94%. This work demonstrates a methodology to prepare flexible synaptic devices with tunable synaptic plasticity and broad-spectrum perception that is potentially applicable to building flexible neuromorphic electronics.

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confidence: 89%

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confidence: 99%

Flexible Optoelectronic Synapses Based on Conjugated Polymer Blends for Ultra Broadband Spectrum Light Perception

Jiang,

Yang,

Yuan

et al. 2024

ACS Materials Lett.

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“…In this study, a series of poly The perception of visual information by an organism is a complex physiological process involving various neurons and synapses (Figure 1a). 18,19 Biological vision was simulated by the artificial photoelectric synapses. Semiconducting block copolymers with novel helical structures were prepared thanks to the inspiration of functional helical structures in nature (Figure 1b), and for the first time, the helical nanowires were utilized as the active layer of synaptic devices (Figure 1c).…”

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confidence: 99%

Helical Nanofiber Photoelectric Synaptic Devices for an Artificial Vision Nervous System

Jiang,

Yang,

et al. 2023

Nano Lett.

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Inspired by the helical structure and the resultant exquisite functions of biomolecules, helical polymers have received increasing attention. Here, a series of poly(3-hexylthiophene)-blockpoly(phenyl isocyanide) (P3HT-b-PPI) copolymers were prepared using a simple one-pot living polymerization method. Interestingly, the P3HT 80 -b-PPI 30 films were found to have a helical nanofiber structure. The corresponding device has superior optoelectronic properties, such as a broadened spectral response range from the visible band to the deep ultraviolet (DUV) and an approximately 5-fold longer carrier decay time after DUV light stimulation. An energy consumption of 1.44 fJ per synaptic event was obtained, which is the lowest energy consumption achieved so far with DUV light stimulation. The encryption and decryption of images are implemented using an array of devices. Finally, a photoreceptor neural pathway was constructed to achieve early warning for the recognition of the display of harmful light. This research provides an effective strategy for the development of a novel optoelectronic synaptic device.

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“…43−47 Moreover, the mechanical integrity of the ambipolar devices can also be enhanced via mixed-dimensional nanoparticle−nanowire p-n channels and bidirectional plasticity of the ambipolar devices has potential uses in reversible information processing and neuromorphic algorithms. 48 Here, an ion-impermeable zero-dimensional inorganic film and ion-permeable one-dimensional organic film were employed as n-type 49,50 and p-type 51−53 integrity and asymmetric bidirectional synaptic plasticity. Being a crucial component of the analogous somatosensory nerves, the device can be exploited to achieve the perception of visible light, signal processing, and behavior driving.…”

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confidence: 99%

“…The electrolyte-type transistor benefits from a high carrier concentration and a low operating frequency due to the unique ion–electronic interface interaction, − which enables switching and gain functionalities in the component. For example, some reports have demonstrated the great potential of the dual-carrier (holes and electrons) strategy for regulating plasticity in the synaptic transistor by utilizing the distinct ion interfacial behaviors on organic and inorganic films, respectively. − Limited by the rare p - type oxide semiconductor (oxygen vacancies can also annihilate holes) − and poor n - type organic semiconductor (species can also interact or react with the injected electrons), − with this carrier complementary strategy, the combination of the channels for inorganic n - type and organic p - type films may be the optimum lineup to acquire the relatively stable bidirectional synaptic plasticity. − Moreover, the mechanical integrity of the ambipolar devices can also be enhanced via mixed-dimensional nanoparticle–nanowire p-n channels and bidirectional plasticity of the ambipolar devices has potential uses in reversible information processing and neuromorphic algorithms …”

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confidence: 99%

Mixed-Dimensional Nanoparticle–Nanowire Channels for Flexible Optoelectronic Artificial Synapse with Enhanced Photoelectric Response and Asymmetric Bidirectional Plasticity

Wei,

Xu,

et al. 2023

Nano Lett.

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A mixed-dimensional dual-channel synaptic transistor composed of inorganic nanoparticles and organic nanowires was fabricated to expand the photoelectric gain range. The device can actualize the sensitization features of the nociceptor and shows improved responsiveness to visible light. Under electrical pulses with different polarities, the apparatus exhibits reconfigurable asymmetric bidirectional plasticity. Moreover, the devices demonstrate good operational tolerance and mechanical stability, retaining more than 60% of their maximum responsiveness after 100 consecutive/bidirectional and 1000 flex/flat operations. The improved photoelectric response of the device endows a high image recognition accuracy of greater than 80%. Asymmetric bidirectional plasticity is used as punishment/reward in a psychological experiment to emulate the improvement of learning motivation and enables real-time forward and backward deflection (+7 and −25°) of artificial muscle. The mixed-dimensional optoelectronic artificial synapses with switchable behavior and electron/hole transport type have important prospects for neuromorphic processing and artificial somatosensory nerves.

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High‐Contrast Bidirectional Optoelectronic Synapses based on 2D Molecular Crystal Heterojunctions for Motion Detection

Cited by 20 publications

References 70 publications

Flexible Optoelectronic Synapses Based on Conjugated Polymer Blends for Ultra Broadband Spectrum Light Perception

Flexible Optoelectronic Synapses Based on Conjugated Polymer Blends for Ultra Broadband Spectrum Light Perception

Helical Nanofiber Photoelectric Synaptic Devices for an Artificial Vision Nervous System

Mixed-Dimensional Nanoparticle–Nanowire Channels for Flexible Optoelectronic Artificial Synapse with Enhanced Photoelectric Response and Asymmetric Bidirectional Plasticity

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