Li‐Ion Synaptic Transistor for Low Power Analog Computing

Fuller, Elliot James; Gabaly, Farid El; Léonard, François; Agarwal, Sapan; Plimpton, Steven J.; Jacobs-Gedrim, Robin; James, Conrad D.; Marinella, Matthew; Talin, A. Alec

doi:10.1002/adma.201604310

Cited by 454 publications

(552 citation statements)

References 51 publications

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“…[108][109][110][111] In addition, electrochemical random-access memory (ECRAM) based on ion intercalation has recently been reported as a promising synaptic cell, showing multi-states and incremental switching with near-ideal switching symmetry and linearity. [29,[112][113][114][115][116][117][118][119] The electrochemically driven ion intercalation process is more controllable than filament-related ion movements in RRAM; therefore, ECRAM also exhibits a much smaller stochasticity. In addition, by borrowing the battery concept, those devices successfully decouple the read and write operations and thus realize low programming energy and long retention time simultaneously.…”

Section: Artificial Synapsesmentioning

confidence: 99%

Bridging Biological and Artificial Neural Networks with Emerging Neuromorphic Devices: Fundamentals, Progress, and Challenges

et al. 2019

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As the research on artificial intelligence booms, there is broad interest in brain‐inspired computing using novel neuromorphic devices. The potential of various emerging materials and devices for neuromorphic computing has attracted extensive research efforts, leading to a large number of publications. Going forward, in order to better emulate the brain's functions, its relevant fundamentals, working mechanisms, and resultant behaviors need to be re‐visited, better understood, and connected to electronics. A systematic overview of biological and artificial neural systems is given, along with their related critical mechanisms. Recent progress in neuromorphic devices is reviewed and, more importantly, the existing challenges are highlighted to hopefully shed light on future research directions.

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Section: Artificial Synapsesmentioning

confidence: 99%

Bridging Biological and Artificial Neural Networks with Emerging Neuromorphic Devices: Fundamentals, Progress, and Challenges

et al. 2019

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“…This kind of chemical 'gating' effect can be obtained by using ions with low energy barrier (for example, Li ions) to drive the charge-discharge redox reactions in the conduction channel in a battery-like fashion. In this case, switching can occur at a very low voltage (for example, 5 mV), resulting in excellent power efficiency 71 . Beyond synaptic behaviours, memristive systems can be used to implement neuronal elements that ultimately receive, process and transmit information in bioinspired computing systems.…”

Section: The Role Of Chemistry and Biological Detailsmentioning

confidence: 99%

The future of electronics based on memristive systems

2018

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“…[270] The brain, a natural computing machine, has a great ability to predict, analyze, and infer links among the events, which are difficult tasks for nowadays computers. Although memristive memory cells are mainly used for artificial synapses, many synaptic or neuron-like transistors using either memristive channel [13,[272][273][274][275][276][277] or dielectric materials [278][279][280][281][282][283][284] have been reported. Recently, the several inspiring developments related to artificial neurons and synapses have been published.…”

Section: Biologically Inspired Hybrid Devicesmentioning

confidence: 99%

Hybrid Silicon Nanowire Devices and Their Functional Diversity

et al. 2019

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In the pool of nanostructured materials, silicon nanostructures are known as conventionally used building blocks of commercially available electronic devices. Their application areas span from miniaturized elements of devices and circuits to ultrasensitive biosensors for diagnostics. In this Review, the current trends in the developments of silicon nanowire‐based devices are summarized, and their functionalities, novel architectures, and applications are discussed from the point of view of analog electronics, arisen from the ability of (bio)chemical gating of the carrier channel. Hybrid nanowire‐based devices are introduced and described as systems decorated by, e.g., organic complexes (biomolecules, polymers, and organic films), aimed to substantially extend their functionality, compared to traditional systems. Their functional diversity is explored considering their architecture as well as areas of their applications, outlining several groups of devices that benefit from the coatings. The first group is the biosensors that are able to represent label‐free assays thanks to the attached biological receptors. The second group is represented by devices for optoelectronics that acquire higher optical sensitivity or efficiency due to the specific photosensitive decoration of the nanowires. Finally, the so‐called new bioinspired neuromorphic devices are shown, which are aimed to mimic the functions of the biological cells, e.g., neurons and synapses.

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Li‐Ion Synaptic Transistor for Low Power Analog Computing

Cited by 454 publications

References 51 publications

Bridging Biological and Artificial Neural Networks with Emerging Neuromorphic Devices: Fundamentals, Progress, and Challenges

Bridging Biological and Artificial Neural Networks with Emerging Neuromorphic Devices: Fundamentals, Progress, and Challenges

The future of electronics based on memristive systems

Hybrid Silicon Nanowire Devices and Their Functional Diversity

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