Chengdong Yao scite author profile

Optoelectronic synaptic devices integrating light-perception and signal-storage functions hold great potential in neuromorphic computing for visual information processing, as well as complex brain-like learning, memorizing, and reasoning. Herein, the successful growth of MoS 2 monolayer arrays assisted by gold nanorods guided precursor nucleation is demonstrated. Optical, spectral, and morphology characterizations of MoS 2 prove that arrayed flakes are homogeneous monolayers, and they are further fabricated as optoelectronic devices showing featured photocurrent loops and stable optical responses. Typical synaptic behaviors of photo-induced short-term potentiation, long-term potentiation, and paired pulse facilitation are recorded under different light stimulations of 450, 532, and 633 nm lasers at various excitation powers. A visual sensing system consisting of 5 × 6 pixels is constructed to simulate the light-sensing image mapped by forgetting curves in real time. Moreover, the system presents the ability of utilizing associated images to restore vague and incomplete memories, which successfully mimics human intelligent behaviors of association memory and logical reasoning. The work emulates the brain-like artificial intelligence using arrayed 2D semiconductors, which paves an avenue to achieve smart retina and complex brain-like system.

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Epitaxial van der Waals contacts for low schottky barrier MoS2 field effect transistors

Liu

Fang

Zhu

et al. 2022

Nano Res.

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Reconfigurable Artificial Synapse Based on Ambipolar Floating Gate Memory

Yao

Huang

et al. 2023

ACS Appl. Mater. Interfaces

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Artificial synapse networks capable of massively parallel computing and mimicking biological neural networks can potentially improve the processing efficiency of existing information technologies. Semiconductor devices functioning as excitatory and inhibitory synapses are crucial for developing intelligence systems, such as traffic control systems. However, achieving reconfigurability between two working modes (inhibitory and excitatory) and bilingual synaptic behavior in a single transistor remains challenging. This study successfully mimics a bilingual synaptic response using an artificial synapse based on an ambipolar floating gate memory comprising tungsten selenide (WSe 2 )/ hexagonal boron nitride (h-BN)/ molybdenum telluride (MoTe 2 ). In this WSe 2 /h-BN/MoTe 2 structure, ambipolar semiconductors WSe 2 and MoTe 2 are inserted as channel and floating gates, respectively, and h-BN serves as the tunneling barrier layer. Using either positive or negative pulse amplitude modulations at the control gate, this device with bipolar channel conduction produced eight distinct resistance states. Based on this, we experimentally projected that we could achieve 490 memory states (210 hole-resistance states + 280 electron-resistance states). Using the bipolar charge transport and multistorage states of WSe 2 /h-BN/MoTe 2 floating gate memory, we mimicked reconfigurable excitatory and inhibitory synaptic plasticity in a single device. Furthermore, the convolution neural network formed by these synaptic devices can recognize handwritten digits with an accuracy of >92%. This study identifies the unique properties of heterostructure devices based on two-dimensional materials as well as predicts their applicability in advanced recognition of neuromorphic computing.

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Chengdong Yao

Multifunctional Optoelectronic Synapses Based on Arrayed MoS₂ Monolayers Emulating Human Association Memory

Epitaxial van der Waals contacts for low schottky barrier MoS2 field effect transistors

Reconfigurable Artificial Synapse Based on Ambipolar Floating Gate Memory

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Chengdong Yao

Multifunctional Optoelectronic Synapses Based on Arrayed MoS2 Monolayers Emulating Human Association Memory

Epitaxial van der Waals contacts for low schottky barrier MoS2 field effect transistors

Reconfigurable Artificial Synapse Based on Ambipolar Floating Gate Memory

Contact Info

Product

Resources

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Multifunctional Optoelectronic Synapses Based on Arrayed MoS₂ Monolayers Emulating Human Association Memory