Optoelectronic Synapses and Photodetectors Based on Organic Semiconductor/Halide Perovskite Heterojunctions: Materials, Devices, and Applications

Guo, Zhang; Zhang, Junyao; Xu, Lei; Wang, Lu; Xiong, Lize; Huang, Jia

doi:10.1002/adfm.202305508

Cited by 32 publications

(14 citation statements)

References 182 publications

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“…Compared with electrical synaptic devices, optical synaptic devices have the function of light perception, so they can be better used for neuromorphic computation of visual perception with the advantages of a more simple-structured system. After optical synaptic devices were proposed, optical synaptic devices for various light wavelengths have attracted the interest of scholars, and two-dimensional materials, chalcogenides, and oxides have been widely studied and cited as optical synaptic devices for different application scenarios. ,− However, due to the high requirements of X-ray synapses on materials and devices, that is, the irradiation resistance of material and high gain of a device with light-induced memory-like behavior, current synaptic devices are mainly concentrated in visible light. As a result, building X-ray synaptic devices becomes a big challenge .…”

Section: Introductionmentioning

confidence: 99%

Reservoir Computing Based on Oxygen-Vacancy-Mediated X-ray Optical Synaptic Device for Medical CT Bone Diagnosis

Liu,

Yu,

Zhang

et al. 2024

ACS Appl. Mater. Interfaces

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Recognition and judgment of X-ray computed tomography (CT) images play a crucial role in medical diagnosis and disease prevention. However, the storage and calculation of the X-ray imaging system applied in the traditional CT diagnosis is separate, and the pathological judgment is based on doctors' experience, which will affect the timeliness and accuracy of decision-making. In this paper, a simplestructured reservoir computing network (RC) is proposed based on Ga 2 O 3 X-ray optical synaptic devices to recognize medical skeletal CT images with high accuracy. Through oxygen vacancy engineering, Ga 2 O 3 X-ray optical synaptic devices with adjustable photocurrent gain and a persistent photoconductivity effect were obtained. By using the Ga 2 O 3 X-ray optical synaptic device as a reservoir, we constructed an RC network for medical skeletal CT diagnosis and verified its image recognition capability using the MNIST data set with an accuracy of 78.08%. In the elbow skeletal CT image recognition task, the recognition rate is as high as 100%. This work constructs a simple-structured RC network for X-ray image recognition, which is of great significance in applications in medical fields.

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Section: Introductionmentioning

confidence: 99%

Reservoir Computing Based on Oxygen-Vacancy-Mediated X-ray Optical Synaptic Device for Medical CT Bone Diagnosis

Liu,

Yu,

Zhang

et al. 2024

ACS Appl. Mater. Interfaces

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“…With the inevitable advent of artificial intelligence that has caused a need for enormous data, conventional computers based on von Neumann architecture are facing severe challenges owing to the separation of the memory and the processor units. , Brain-like neuromorphic computers based on synaptic devices have thereby been proposed. − The concept of the brain-inspired computing system relies on resistive switching and an associated memory phenomenon. In this direction, a range of materials, such as metal oxides, organic semiconductors, phase change materials, perovskites, ,− 2D materials, − etc., are being considered. As device structures, two and three terminal device geometries in the form of memristors, ,, and field-effect transistors, , respectively, have been studied to successfully emulate the diverse synaptic functions of the human brain.…”

Section: Introductionmentioning

confidence: 99%

“…The photonic synaptic devices, on the other hand, involve optical signal(s) in the synaptic processes. The synapses emulate the human visual system of signal-sensing and processing by the retina and image recognition toward the evolution of optical wireless communications . The devices, which are based on optoelectronic memristors, can directly sense the optical signals and process the light information to serve as artificial optical synapses .…”

Section: Introductionmentioning

confidence: 99%

Introducing Chiro-optical Activities in Photonic Synapses for Neuromorphic Computing and In-Memory Logic Operations

Dan,

Paramanik,

Pal

2024

ACS Nano

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In artificial synaptic devices aimed at mimicking neuromorphic computing systems, electrical or optical pulses, or both, are generally used as stimuli. In this work, we introduce chiral materials for tailoring the characteristics of photonic synaptic devices to achieve handedness-dependent neuromorphic computing and in-memory logic gates. In devices based on a pair of chiral perovskites, the use of circularly polarized light (CPL) as the optical stimuli mimicked a series of electrical and opto-synaptic functionalities in order to emulate the multifunctional complex behavior of the human brain. Upon illumination in this two-terminal device, anisotropy in current has been observed due to the out-ofplane carrier transport, originating from spin-selective carrier transport. More importantly, the logic gate achieved in devices based on optoelectronic memristors turned out to be chirality-dependent; while an R-device functioned as an AND gate, the device based on the same perovskite of the opposite chirality (S-device) acted as a NOR gate toward in-memory logic operations. These findings in chiral perovskite-based artificial synapses can identify further strategies for future neuromorphic computing, vision simulation, and artificial intelligence.

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“…[6,7] As one type of potential component unit for constructing ANNs, artificial synapses with distinctive performance have recently gained growing interest in information technology and medical health. [8][9][10][11][12][13][14][15] As artificial intelligence replaces human labor and progressively enters human life, more and more intelligent applications will involve high-temperature scenarios, which poses a challenge to the heat resistance of artificial synaptic devices. [16] Specifically, biomedical electronic devices integrated into ANNs for clinical use should withstand sterilization conditions necessary to prevent infection at the temperature above 121°C.…”

Section: Introductionmentioning

confidence: 99%

Organic High‐Temperature Synaptic Phototransistors for Energy‐Efficient Neuromorphic Computing

Guo,

Zhang,

Yang

et al. 2023

Advanced Materials

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Organic optoelectronic synaptic devices that can reliably operate in high‐temperature environments (i.e., beyond 121°C) or remain stable after high‐temperature treatments have significant potential in biomedical electronics and bionic robotic engineering. However, it is challenging to acquire this type of organic devices considering the thermal instability of conventional organic materials and the degradation of photoresponse mechanisms at high temperatures. Here, high‐temperature synaptic phototransistors (HTSPs) based on thermally stable semiconductor polymer blends as the photosensitive layer are developed, successfully simulating fundamental optical‐modulated synaptic characteristics at a wide operating temperature range from room temperature to 220°C. Robust optoelectronic performance can be observed in HTSPs even after experiencing 750 h of the double 85 testing due to the enhanced operational reliability. Using HTSPs, Morse‐code optical decoding scheme and the visual object recognition capability are also verified at elevated temperatures. Furthermore, flexible HTSPs are fabricated, demonstrating an ultralow power consumption of 12.3 aJ per synaptic event at a low operating voltage of −0.05 mV. Overall, the conundrum of achieving reliable optical‐modulated neuromorphic applications while balancing low power consumption can be effectively addressed. This research opens up a simple but effective avenue for the development of high‐temperature and energy‐efficient wearable optoelectronic devices in neuromorphic computing applications.

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Optoelectronic Synapses and Photodetectors Based on Organic Semiconductor/Halide Perovskite Heterojunctions: Materials, Devices, and Applications

Cited by 32 publications

References 182 publications

Reservoir Computing Based on Oxygen-Vacancy-Mediated X-ray Optical Synaptic Device for Medical CT Bone Diagnosis

Reservoir Computing Based on Oxygen-Vacancy-Mediated X-ray Optical Synaptic Device for Medical CT Bone Diagnosis

Introducing Chiro-optical Activities in Photonic Synapses for Neuromorphic Computing and In-Memory Logic Operations

Organic High‐Temperature Synaptic Phototransistors for Energy‐Efficient Neuromorphic Computing

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