Tunable flexible artificial synapses: a new path toward a wearable electronic system

Yang, Kunlong; Yuan, Sijian; Huan, Yuxiang; Wang, Jiao; Tu, Li; Xu, Jiawei; Zou, Zhuo; Zhan, Yiqiang; Zheng, Lirong; Seoane, Fernando

doi:10.1038/s41528-018-0033-1

Cited by 33 publications

(33 citation statements)

References 40 publications

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“…1A. The understandings in biology and advances in materials and electronic technologies have led to the recent development of artificial synaptic devices, mostly in rigid or flexible formats (10)(11)(12)(13)(14)(15)(16)(17), to emulate the biological counterparts toward emerging applications, such as parallel processing (18)(19)(20)(21)(22)(23), low-power computing (10,24), neuroprosthetics (11,25), etc. Artificial synapses, which are very stretchable similar to those that appear in soft animals, are key to enabled neurological functions in soft machines and many other applications, such as neuroprosthetics (11,(26)(27)(28)(29).…”

Section: Introductionmentioning

confidence: 99%

Stretchable elastic synaptic transistors for neurologically integrated soft engineering systems

et al. 2019

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Artificial synaptic devices that can be stretched similar to those appearing in soft-bodied animals, such as earthworms, could be seamlessly integrated onto soft machines toward enabled neurological functions. Here, we report a stretchable synaptic transistor fully based on elastomeric electronic materials, which exhibits a full set of synaptic characteristics. These characteristics retained even the rubbery synapse that is stretched by 50%. By implementing stretchable synaptic transistor with mechanoreceptor in an array format, we developed a deformable sensory skin, where the mechanoreceptors interface the external stimulations and generate presynaptic pulses and then the synaptic transistors render postsynaptic potentials. Furthermore, we demonstrated a soft adaptive neurorobot that is able to perform adaptive locomotion based on robotic memory in a programmable manner upon physically tapping the skin. Our rubbery synaptic transistor and neurologically integrated devices pave the way toward enabled neurological functions in soft machines and other applications.

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Section: Introductionmentioning

confidence: 99%

Stretchable elastic synaptic transistors for neurologically integrated soft engineering systems

et al. 2019

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“…In the past few years, scientists around the world have tried to mimic the signal transmission process and various types of synaptic plasticity in the brain, although the brain mystery has not yet been fully revealed . The realization of “brain‐like computing” can start from simulating the structure and function of neural networks and artificial synapses, without waiting for neuroscientists and cognitive scientists to fully understand the brain's mechanism, which may even need the exploration process to be longer.…”

Section: Biological Synapses and Synaptic Plasticitymentioning

confidence: 99%

Recent Advances in Transistor‐Based Artificial Synapses

Dai

Zhao

Wang

et al. 2019

Adv Funct Materials

447

422

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Simulating biological synapses with electronic devices is a re-emerging field of research. It is widely recognized as the first step in hardware building brain-like computers and artificial intelligent systems. Thus far, different types of electronic devices have been proposed to mimic synaptic functions. Among them, transistor-based artificial synapses have the advantages of good stability, relatively controllable testing parameters, clear operation mechanism, and can be constructed from a variety of materials. In addition, they can perform concurrent learning, in which synaptic weight update can be performed without interrupting the signal transmission process. Synergistic control of one device can also be implemented in a transistor-based artificial synapse, which opens up the possibility of developing robust neuron networks with significantly fewer neural elements. These unique features of transistor-based artificial synapses make them more suitable for emulating synaptic functions than other types of devices. However, the development of transistor-based artificial synapses is still in its very early stages. Herein, this article presents a review of recent advances in transistor-based artificial synapses in order to give a guideline for future implementation of synaptic functions with transistors. The main challenges and research directions of transistor-based artificial synapses are also presented.In the nerve system, a synapse is a specialized structure that allows a neuron to pass chemical or electrical signals to another Figure 2. a) Schematic illustration (top) and microscopy image (bottom) of flexible synaptic transistors based on a random matrix of semiconducting CNTs. b) Case 1: the amplitudes of V LTP and V LTP are greater than other cases; thus, NL is the highest and ΔG is the largest. c) Case 2: the amplitudes of V LTP and V LTP are smaller than in case 1; thus, NL and ΔG are lower. d) Case 3: if the CNT transistor without the Au floating gate is used for the synaptic transistor, NL and ΔG are considerably smaller than in the other cases due to the limited charge storage space. Reproduced with permission. [87]

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“…Two-terminal memristive devices are promising candidates to act as a compact electronic element and have been widely demonstrated in the pursuit of certain synaptic functions [8][9][10] . Specifically, synaptic operations, including long-term potentiation/depression (LTP/LTD), short-term potentiation/depression (STP/STD), spiketiming-dependent plasticity (STDP) learning rules, paired-pulse facilitation (PPF), and low-power consumption have been extensively simulated in these electronic synapses (e-synapses) [11][12][13][14][15][16][17][18][19][20][21][22][23][24][25][26][27][28] . However, e-synapses usually suffer from unavoidable temporal (cycle-to-cycle) and spatial (device-to-device) variations due to their intrinsic working mechanism and structure interaction.…”

Section: Introductionmentioning

confidence: 99%

Ultrathin electronic synapse having high temporal/spatial uniformity and an Al2O3/graphene quantum dots/Al2O3 sandwich structure for neuromorphic computing

et al. 2019

NPG Asia Mater

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An electronic synapse (e-synapse) based on memristive switching is a promising electronic element that emulates a biological synapse to realize neuromorphic computing. However, the complex resistive switching process it relies on hampers the reproducibility of its performance. Thus, achievement of a reproducible electronic synapse with a high rate of finished products has become a significant challenge in the development of an artificial intelligent circuit. Here, we demonstrate an ultrathin e-synapse having high yield (>95%), minimal performance variation, and extremely low power consumption based on an Al 2 O 3 /graphene quantum dots/Al 2 O 3 sandwich structure that was fabricated using atomic layer deposition. The e-synapse showed both high device-to-device and cycle-to-cycle reproducibility with high stability, endurance, and switching uniformity, because the essential synaptic behaviors could be observed. This implementation of an e-synapse with an Al 2 O 3 /graphene quantum dots/Al 2 O 3 structure should intensify motivation for engineering e-synapses for neuromorphic computing.

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Tunable flexible artificial synapses: a new path toward a wearable electronic system

Cited by 33 publications

References 40 publications

Stretchable elastic synaptic transistors for neurologically integrated soft engineering systems

Stretchable elastic synaptic transistors for neurologically integrated soft engineering systems

Recent Advances in Transistor‐Based Artificial Synapses

Ultrathin electronic synapse having high temporal/spatial uniformity and an Al2O3/graphene quantum dots/Al2O3 sandwich structure for neuromorphic computing

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