Coexistance of the Negative Photoconductance Effect and Analogue Switching Memory in the CuPc Organic Memristor for Neuromorphic Vision Computing

Liao, Changrong; Liu, Dong; Liu, Zheng; Wang, Jinchengyan; Xie, Xuesen; Li, Jie; Zhou, Guangdong

doi:10.1021/acs.jpclett.4c01071

J. Phys. Chem. Lett.

2024

DOI: 10.1021/acs.jpclett.4c01071

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Coexistance of the Negative Photoconductance Effect and Analogue Switching Memory in the CuPc Organic Memristor for Neuromorphic Vision Computing

Changrong Liao,

Dong Liu,

Zheng Liu

et al.

Abstract: A bioinspired in-sensing computing paradigm using emerging photoelectronic memristors pursues multifunctionality with low power consumption and high efficiency for processing large amounts of sensing information. An organic semiconductor memristor strategy based on the CuPc functional layer integrates a negative photoconductance (NPC) effect and an analogue switching memory (ASM) effect in the same pixel. The NPC effect, present in the pure capacitance state at low bias voltage, provides high-performance short… Show more

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Near-Infrared Response Organic Synaptic Transistor for Dynamic Trace Extraction

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et al. 2024

J. Phys. Chem. Lett.

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The development of neuromorphic hardware capable of detecting and recognizing moving targets through an in-sensor computing strategy is considered to be an important component of the construction of edge computing systems with distributed computation. In addition to responsiveness to visible light, the implementation of neuromorphic hardware should also demonstrate the ability to sense and process nonvisible light, which is essential for tracking target object trajectories in specialized environments. In this work, we fabricated an organic synaptic transistor with a near-infrared (NIR) response by incorporating doped LaF 3 : Yb/Ho upconversion quantum dots (UCQDs) into the channel of a Poly3hexylthiophene (P3HT)-based organic field effect transistor (FET), serving as charge trapping and infrared sensing sites. The obtained synaptic transistor not only replicates common synaptic behaviors when exposed to NIR illumination but also demonstrates potential applications for the dynamic trajectory recognition of animals in the dark. Compared to other monitoring technologies, P3HT transistors doped with LaF 3 : Yb/Ho UCQDs exhibit distinct advantages, including a NIR response, high-efficiency computing, and sensitivity, which provide an experimental foundation and a design reference for the development of next-generation intelligent dynamic image recognition systems.

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Emerging materials for resistive switching memories: Prospects for enhanced sustainability and performance for targeted applications

Loizos,

Rogdakis,

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et al. 2024

APL Energy

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Resistive switching (RS) memories are novel devices that have attracted significant attention recently in view of their potential integration in deep neural networks for intense big data processing within the explosive artificial intelligence era. While oxide- or silicon-based memristive devices have been thoroughly studied and analyzed, there are alternative material technologies compatible with lower manufacturing cost and less environmental impact exhibiting RS characteristics, thus providing a versatile platform for specific in-memory computing and neuromorphic applications where sustainability is a priority. The manufacturing of these emerging RS technologies is based on solution-processed methods at low temperatures onto flexible substrates, and in some cases, the RS active layer is composed of natural, environmentally friendly materials replacing expensive deposition methods and critical raw and toxic materials. In this Perspective, we provide an overview of recent developments in the field of solution-processed and sustainable RS devices by providing insights into their fundamental properties and switching mechanisms, categorizing key figures of merit while showcasing representative use cases of applications of each material technology. The challenges and limitations of these materials for practical applications are analyzed along with suggestions to resolve these pending issues.

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Coexistance of the Negative Photoconductance Effect and Analogue Switching Memory in the CuPc Organic Memristor for Neuromorphic Vision Computing

Cited by 3 publications

References 36 publications

Investigation of the TaO unipolar switching memory on high efficiency computing

Investigation of the TaO unipolar switching memory on high efficiency computing

Near-Infrared Response Organic Synaptic Transistor for Dynamic Trace Extraction

Emerging materials for resistive switching memories: Prospects for enhanced sustainability and performance for targeted applications

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