A molecular neuromorphic network device consisting of single-walled carbon nanotubes complexed with polyoxometalate

Tanaka, Hirofumi; Akai‐Kasaya, Megumi; TermehYousefi, Amin; Hong, Liu; Fu, Lingxiang; Tamukoh, Hakaru; Tanaka, Daisuke; Asai, Tetsuya; Ogawa, Takuji

doi:10.1038/s41467-018-04886-2

Cited by 114 publications

(130 citation statements)

References 35 publications

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“…Inspired by the diverse perceptive functions, such as memory, learning, attention, and visual sensing, as well as numerous advantages, for example, relatively low energy consumption and robustness of the biological brains, innovative artificial neuromorphic engineering with merits of good fault and error tolerance and massive parallelism has been developed . Functional characteristics of the chemical systems can be emulated and hence break through the von Neumann bottleneck of the traditional computers .…”

Section: Introductionmentioning

confidence: 99%

Flexible Pyrene/Phenanthro[9,10‐d]imidazole‐Based Memristive Devices for Mimicking Synaptic Plasticity

Ren

Chang

Ting

et al. 2019

Advanced Intelligent Systems

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Emulation of memory and learning functionalities of biological synapses using a two-terminal electronic device with bidirectional progressive conductance modulation is an indispensable move toward the development of bio-inspired neuromorphic networks. Herein, a small molecule 1-phenyl-2-(4-(pyren-1-yl) phenyl)-1H-phenanthro[9,10-d]imidazole (pPPI) is synthesized, and an organic synaptic device is investigated with bipolar resistive switching characteristics and bidirectional gradual conductance regulation for the first time. A facile solution-processing approach can be used to deposit a uniform active layer on flexible substrates. Our pPPI-based nonvolatile memory presents a superior electrical performance, such as relatively stable and reproducible bipolar resistive switching phenomena and a robust data retention capability. In particular, our device displays a remarkably large switching window of around 7.0 Â 10 7 , which is a record ON/OFF ratio compared with other small molecule-based memories up to now. In addition, comprehensive cognitive functions of chemical synapses, for example, the excitatory postsynaptic current (EPSC), paired-pulse facilitation/depression (PPF/PPD), spike-rate-dependent plasticity (SRDP), and spike-time-dependent plasticity (STDP) are successfully achieved. Our achievement of a synaptic device based on small molecules may boost the development of bio-inspired neuromorphic systems using organic electronics.

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Section: Introductionmentioning

confidence: 99%

Flexible Pyrene/Phenanthro[9,10‐d]imidazole‐Based Memristive Devices for Mimicking Synaptic Plasticity

Ren

Chang

Ting

et al. 2019

Advanced Intelligent Systems

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“…Despite a bright future prospective for the development of next‐generation artificial intelligence (AI) systems, it is hard for such rigid top‐down architectures to emulate most typical features of biological neural networks such as high connectivity, adaptability through reconnection and rewiring, and long‐range spatio‐temporal correlation. Alternative ways using unconventional systems consisting of many interacting nano‐parts have been proposed for the realization of biologically plausible architectures where the emergent behavior arises from a complexity similar to that of biological neural circuits . However, these systems were unable to demonstrate bio‐realistic implementation of structural plasticity including reweighting and rewiring and spatio‐temporal processing of input signals similarly to our brain.…”

mentioning

confidence: 99%

Brain‐Inspired Structural Plasticity through Reweighting and Rewiring in Multi‐Terminal Self‐Organizing Memristive Nanowire Networks

Milano

Pedretti

Fretto

et al. 2020

Advanced Intelligent Systems

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Acting as artificial synapses, two‐terminal memristive devices are considered fundamental building blocks for the realization of artificial neural networks. Current memristive crossbar architectures demonstrate the implementation of neuromorphic computing paradigms, although they are unable to emulate typical features of biological neural networks such as high connectivity, adaptability through reconnection and rewiring, and long‐range spatio‐temporal correlation. Herein, self‐organizing memristive random nanowire (NW) networks with functional connectivity able to display homo‐ and heterosynaptic plasticity is reported thanks to the mutual electrochemical interaction among memristive NWs and NW junctions. In particular, it is shown that rewiring and reweighting effects observed in single NWs and single NW junctions, respectively, are responsible for structural plasticity of the network under electrical stimulation. Such biologically inspired systems allow a low‐cost realization of neural networks that can learn and adapt when subjected to multiple external stimuli, emulating the experience‐dependent synaptic plasticity that shape the connectivity and functionalities of the nervous system that can be exploited for hardware implementation of unconventional computing paradigms.

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“…In addition, a techniques for selectively binding specific molecular anchoring groups on specific targeting locations is highly demanded as well to create multi‐functional integrated molecular circuits [135] . As the recent outstanding advances have demonstrated, [136,137] extensive collaborations among experts in physics, chemistry, material science, biology, electrical and mechanical engineering will allow us to achieve robust photoswitching molecular systems and to move forward for the future applications of molecular electronics [138–140] …”

Section: Discussionmentioning

confidence: 99%

Photoswitching Molecular Junctions: Platforms and Electrical Properties

Kim

2020

ChemPhysChem

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Remarkable advances in technology have enabled the manipulation of individual molecules and the creation of molecular electronic devices utilizing single and ensemble molecules. Maturing the field of molecular electronics has led to the development of functional molecular devices, especially photoswitching or photochromic molecular junctions, which switch electronic properties under external light irradiation. This review introduces and summarizes the platforms for investigating the charge transport in single and ensemble photoswitching molecular junctions as well as the electronic properties of diverse photoswitching molecules such as diarylethene, azobenzene, dihydropyrene, and spiropyran. Furthermore, the article discusses the remaining challenges and the direction for moving forward in this area for future photoswitching molecular devices.

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A molecular neuromorphic network device consisting of single-walled carbon nanotubes complexed with polyoxometalate

Cited by 114 publications

References 35 publications

Flexible Pyrene/Phenanthro[9,10‐d]imidazole‐Based Memristive Devices for Mimicking Synaptic Plasticity

Flexible Pyrene/Phenanthro[9,10‐d]imidazole‐Based Memristive Devices for Mimicking Synaptic Plasticity

Brain‐Inspired Structural Plasticity through Reweighting and Rewiring in Multi‐Terminal Self‐Organizing Memristive Nanowire Networks

Photoswitching Molecular Junctions: Platforms and Electrical Properties

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