Vertical MoS<sub>2</sub> Double-Layer Memristor with Electrochemical Metallization as an Atomic-Scale Synapse with Switching Thresholds Approaching 100 mV

Xu, Ruijuan; Jang, Hee-Chang; Lee, Min‐Hyun; Amanov, Dovran; Cho, Yeonchoo; Kim, Haeryong; Park, Seongjun; Shin, Hyeon‐Jin; Ham, Donhee

doi:10.1021/acs.nanolett.8b05140

Cited by 325 publications

(288 citation statements)

References 40 publications

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“…Long‐term retention (10 3 s) was measured after ten consecutive negative pulses (pulse width:100 ns, amplitude: −4 V), as shown in Figure 3j. The energy consumption of our flexible MoS 2 ‐based device was compared with other synapses, including biological and electronic synapses, [ 5,6,10,44,46–56 ] and its advantages are demonstrated in Figure 3k. The energy consumption of our synaptic device was orders of magnitude lower than that of biological systems (10 fJ per synaptic event).…”

Section: Figurementioning

confidence: 99%

Ultralow Power Wearable Heterosynapse with Photoelectric Synergistic Modulation

et al. 2020

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which consume 10 fJ per synaptic event. Previous reports have proposed various artificial synaptic devices for simulating long-term and short-term plasticity. [5][6][7][8][9] Although the development of artificial synaptic architectures has achieved energy consumption down to the femtojoule level, [10] it is hard to achieve lower levels due to the slow response time and highlevel post-synaptic current (PSC). These problems lead to a bottleneck in reducing the power of synaptic weights update. Hence, designing an appropriate device with high-speed program and low-level current are necessary for solving energy consumption problems.Most previous reports were limited to single devices with simple connections and pre-and post-synaptic learning rules, such as excitatory post-synaptic current (EPSC), inhibitory post-synaptic current (IPSC), short-term plasticity (STP), paired pulse facilitation/depression (PPF/PPD), spike time-dependent plasticity (STDP), learning-forgetting-relearning behaviors etc. [11][12][13] The global synapses in neural networks with interconnections to tens of thousands of other synapses for information transmission by neurotransmitters are fundamental in massive parallelism, but are usually overlooked. In contrast to homosynapse, heterosynapse is a basic part of simplified global neural network and have multi-terminal configurations, including pre-, post-, and modulatory-synapse (mod-synapse). [14] Heterosynapse plays key roles in biological functions, including long-term memory for synaptic growth and associative learning. [15,16] Therefore, it is important to simulate synaptic features with responses to modu latory terminal. As a novel gate-control mode, optical control could realize multi-terminal neuromodulations in heterosynapse, with the advantages of reduced thermal loss and simple operating mode. To better understand the complex global neuromodulations in heterosynapse, optoelectronic materials should be meticulously selected for multi-terminal synapses' construction.In another aspect, 2D transition metal dichalcogenides (TMDCs) have attracted increasing attention as promising candidates for next-generation flexible multifunctional electronics due to their superior mechanical flexibility, unique electrical, and optical properties. [17][18][19][20] For example, MoS 2based multi-bit memory exhibits photoelectronic non-volatile Although the energy consumption of reported neuromorphic computing devices inspired by biological systems has become lower than traditional memory, it still remains greater than bio-synapses (≈10 fJ per spike). Herein, a flexible MoS 2 -based heterosynapse is designed with two modulation modes, an electronic mode and a photoexcited mode. A one-step mechanical exfoliation method on flexible substrate and low-temperature atomic layer deposition process compatible with flexible electronics are developed for fabricating wearable heterosynapses. With a pre-spike of 100 ns, the synaptic device exhibits ultralow energy consumption of 18.3 aJ per spike in long-term potentiat...

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Section: Figurementioning

confidence: 99%

Ultralow Power Wearable Heterosynapse with Photoelectric Synergistic Modulation

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“…As shown in Figure 4(f), the resistance of VOCl based memristive device gradually shows an increase or a reduction with consecutive negative (−1.15 V, 500 µs) or positive (1.6 V, 50 µs) voltage pulses, respectively. This suggests that our VOCl based memristors have potential applications in neuromorphic computing [48,[52][53][54][55][56][57].…”

Section: Resultsmentioning

confidence: 85%

Chemical vapor deposition synthesis of two-dimensional freestanding transition metal oxychloride for electronic applications

Yan

Wang

et al. 2019

Sci. China Inf. Sci.

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“…In fact, various working principles and structure-property relations exist despite the structural similarity of 2D TMDs. For instance, 2D TMD-based vertical memristive devices are able to tune multiple resistances by forming and rupturing conductive filaments through the migration of ions stemming from their electrodes ( Dev et al., 2020 ; Xu et al., 2019 ). The spatial pathways of these ions can be further tuned by the intrinsically existing in-plane grain boundaries of 2D TMD layers ( Sangwan et al., 2015 ), as well as by the externally introduced intercalations in between each 2D layer ( Zhang et al., 2019 ; Zhu et al., 2019 ).…”

Section: Promise Of 2d Materials For Neuromorphic Applicationmentioning

confidence: 99%

“…Their desirable properties, including atomic thickness, dangling-bond-free surfaces, mechanical strength, high integration density, tunable electrical transport, and optical properties, as well as low energy consumption, make them ideal candidates for applications in a wide range of electronic devices ( Gupta et al., 2015 ; Mas-Ballesté et al., 2011 ; Xia et al., 2017 ). More recently, the applications of 2D materials have been extensively studied for energy-efficient and high-performing artificial synapses ( Arnold et al., 2017 ; Chen et al., 2019c ; Dev et al., 2020 ; Hu et al., 2019 ; Jiang et al., 2017 ; Kalita et al., 2019 ; Kim et al., 2019c ; Krishnaprasad et al., 2019 ; Kumar et al., 2019 ; Li et al., 2018 ; Liu et al., 2019 ; Mao et al., 2019 ; Paul et al., 2019 ; Pradhan et al., 2020 ; Xie et al., 2018a , 2018b ; Xu et al., 2019 ; Yan et al., 2019a ; Yi et al., 2018 ; Zhu et al., 2019 ). Furthermore, owing to their dangling-bonds-free surface and atomically thin nature, a variety of 2D materials-based heterostructures have been developed in spite of their lattice mismatch ( Novoselov et al., 2016 ).…”

Section: Introductionmentioning

confidence: 99%

“…Furthermore, owing to their dangling-bonds-free surface and atomically thin nature, a variety of 2D materials-based heterostructures have been developed in spite of their lattice mismatch ( Novoselov et al., 2016 ). 2D layered materials can be utilized as active materials in diode-type neuromorphic device architecture with two-electrode configuration, allowing for the storage and updating of synaptic weights via various mechanisms, e.g., the formation of filaments ( Lee et al., 2018 ; Shi et al., 2018 ; Xu et al., 2019 ), the transformation of phases ( Zhu et al., 2019 ), or redistribution of atomic vacancies ( Zhu et al., 2019 ). The unrivaled thinness of 2D materials also enables rapid electrical switching in memristor devices circumventing short channel effects, leading to improved energy efficiency ( Stanford et al., 2018 ).…”

Section: Introductionmentioning

confidence: 99%

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Two-Dimensional Near-Atom-Thickness Materials for Emerging Neuromorphic Devices and Applications

Mofid

et al. 2020

iScience

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Summary Two-dimensional (2D) layered materials and their heterostructures have recently been recognized as promising building blocks for futuristic brain-like neuromorphic computing devices. They exhibit unique properties such as near-atomic thickness, dangling-bond-free surfaces, high mechanical robustness, and electrical/optical tunability. Such attributes unattainable with traditional electronic materials are particularly promising for high-performance artificial neurons and synapses, enabling energy-efficient operation, high integration density, and excellent scalability. In this review, diverse 2D materials explored for neuromorphic applications, including graphene, transition metal dichalcogenides, hexagonal boron nitride, and black phosphorous, are comprehensively overviewed. Their promise for neuromorphic applications are fully discussed in terms of material property suitability and device operation principles. Furthermore, up-to-date demonstrations of neuromorphic devices based on 2D materials or their heterostructures are presented. Lastly, the challenges associated with the successful implementation of 2D materials into large-scale devices and their material quality control will be outlined along with the future prospect of these emergent materials.

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Vertical MoS₂ Double-Layer Memristor with Electrochemical Metallization as an Atomic-Scale Synapse with Switching Thresholds Approaching 100 mV

Cited by 325 publications

References 40 publications

Ultralow Power Wearable Heterosynapse with Photoelectric Synergistic Modulation

Ultralow Power Wearable Heterosynapse with Photoelectric Synergistic Modulation

Chemical vapor deposition synthesis of two-dimensional freestanding transition metal oxychloride for electronic applications

Two-Dimensional Near-Atom-Thickness Materials for Emerging Neuromorphic Devices and Applications

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Vertical MoS2 Double-Layer Memristor with Electrochemical Metallization as an Atomic-Scale Synapse with Switching Thresholds Approaching 100 mV

Cited by 325 publications

References 40 publications

Ultralow Power Wearable Heterosynapse with Photoelectric Synergistic Modulation

Ultralow Power Wearable Heterosynapse with Photoelectric Synergistic Modulation

Chemical vapor deposition synthesis of two-dimensional freestanding transition metal oxychloride for electronic applications

Two-Dimensional Near-Atom-Thickness Materials for Emerging Neuromorphic Devices and Applications

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Vertical MoS₂ Double-Layer Memristor with Electrochemical Metallization as an Atomic-Scale Synapse with Switching Thresholds Approaching 100 mV