Emerging Memory Devices for Neuromorphic Computing

Upadhyay, Navnidhi K.; Jiang, Hao; Wang, Zhongrui; Asapu, Shiva; Xia, Qiangfei; Yang, J. Joshua

doi:10.1002/admt.201800589

Cited by 361 publications

(253 citation statements)

References 74 publications

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“…[80] Copyright 2017, John Wiley & Sons, Inc. g,h) Reproduced with permission. [3,24,[134][135][136][137][138] The emulation of transition between opposite biological behaviors, like excitatory/inhibitory and facilitation/depression, requires fabrication of synaptic devices with high tunability. www.advelectronicmat.de models, learning and memory processes depend on synaptic plasticity (also known as weight).…”

Section: Applications In Neuromorphic Computingmentioning

confidence: 99%

2D Layered Materials for Memristive and Neuromorphic Applications

Wang

Meng

et al. 2019

Adv Elect Materials

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demonstrated that the memristive devices exhibit many promising features, [3][4][5][6][7][8] such as non-volatility, high speed switching, high endurance, high-density integration, CMOS-compatible fabrication, and so on. These features make them ideal candidates for applications in memory devices, [3,5,9] in-memory computing, [3,[10][11][12] and edge computing. [13,14] The working principle of the TMOs-based memristive devices relies on ion drift or diffusion, which resembles motion of ions in the biological neurons and synapses. The ionic motions exhibit dynamic behaviors. Thus, the memristive devices can be used to emulate the synaptic plasticity [15] and neurons. [16][17][18] Compared to traditional silicon synapses [19][20][21] and neurons [22,23] requiring complex circuits, such emerging memristive devices have compact structures and enhanced func-

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Section: Applications In Neuromorphic Computingmentioning

confidence: 99%

2D Layered Materials for Memristive and Neuromorphic Applications

Wang

Meng

et al. 2019

Adv Elect Materials

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“…Neuromorphic computing (NC) is emerging as a new paradigm in the current Big Data era with the aim to overcome the technological bottlenecks of conventional von Neumann architectures 1–10. This new form of data storage and processing finds inspiration from the working principles of the human brain, which is characterized by massive parallel reconfigurable connections (synapsis) linking a large number of memory centers (neurons).…”

Section: Figurementioning

confidence: 99%

“…On the other hand, it has been established that a sizable, nonvolatile change in resistance can be induced in FE oxides upon application of an external voltage 11,12. The switching of the resistance, which can be configured with respect to multiple values, may be utilized for the implementation of nonvolatile multilevel memories—the so‐called memristors—with envisioned synapse‐like functionalities 1,2,13…”

Section: Figurementioning

confidence: 99%

“…Indeed, FE devices based on the purely electrostatic preservation of charge carriers require a high crystalline quality with a low amount of structural defects in order to avoid the onset of leakage currents 23,25,26. On the contrary, a common approach to realize resistive switching in FE memristors is to exploit the formation of preferential conducting paths due to the presence of structural defects 1,27. Therefore, the ability to manipulate the amount of structural defects, such as the concentration of oxygen vacancies, in a controlled manner via an external control parameter is a promising strategy to adjust the electrostatic and resistive degrees of freedom in FE oxides.…”

Section: Figurementioning

confidence: 99%

“…[11,12] The switching of the resistance, which can be configured with respect to multi ple values, may be utilized for the implementation of nonvolatile multilevel memories-the so-called memristors-with envisioned synapse-like functionalities. [1,2,13] Owing to their different physical origin, polarization and resistive switching processes are known to have a competing character in FE oxides. Which of the two processes predominates depends to a large extent on the structural features of the considered FE oxide.…”

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confidence: 99%

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Configurable Resistive Response in BaTiO₃ Ferroelectric Memristors via Electron Beam Radiation

et al. 2020

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Ferroelectric oxide memristors are currently in the highlights of a thriving area of research aiming at the development of nonvolatile, adaptive memories for applications in neuromorphic computing. However, to date a precise control of synapse‐like functionalities by adjusting the interplay between ferroelectric polarization and resistive switching processes is still an ongoing challenge. Here, it is shown that by means of controlled electron beam radiation, a prototypical ferroelectric film of BaTiO3 can be turned into a memristor with multiple configurable resistance states. Ex situ and in situ analyses of current/voltage characteristics upon electron beam exposure confirm the quasi‐continuous variation of BaTiO3 resistance up to two orders of magnitude under the typical experimental conditions employed in electron beam patterning and characterization techniques. These results demonstrate an unprecedented effective route to locally and scalably engineering multilevel ferroelectric memristors via application of moderate electron beam radiation.

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Electrolyte‐Gated Synaptic Transistor with Oxygen Ions

Huang

Chen

Zhang

et al. 2019

Adv Funct Materials

118

101

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Artificial synaptic devices are the essential hardware of neuromorphic computing systems, which can simultaneously perform signal processing and information storage between two neighboring artificial neurons. Emerging electrolyte-gated transistors have attracted much attention for efficient synaptic emulation by using an addition gate terminal. Here, an electrolyte-gated synaptic device based on the SrCoO x (SCO) films is proposed. It is demonstrated that the reversible modulation of SCO phase transforms the brownmillerite SrCoO 2.5 and perovskite SrCoO 3−δ , through controlling the insertion and extraction of oxygen ions with electrolyte gating. Nonvolatile multilevel conduction states can be realized in the SCO films following this route. The synaptic functions such as the long-term potentiation and depression of synaptic weight, spike-timing-dependent plasticity, as well as spiking logic operations in the device are successfully mimicked. These results provide an alternative avenue for future neuromorphic devices via electrolyte-gated transistors with oxygen ions.

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Emerging Memory Devices for Neuromorphic Computing

Cited by 361 publications

References 74 publications

2D Layered Materials for Memristive and Neuromorphic Applications

2D Layered Materials for Memristive and Neuromorphic Applications

Configurable Resistive Response in BaTiO₃ Ferroelectric Memristors via Electron Beam Radiation

Electrolyte‐Gated Synaptic Transistor with Oxygen Ions

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Emerging Memory Devices for Neuromorphic Computing

Cited by 361 publications

References 74 publications

2D Layered Materials for Memristive and Neuromorphic Applications

2D Layered Materials for Memristive and Neuromorphic Applications

Configurable Resistive Response in BaTiO3 Ferroelectric Memristors via Electron Beam Radiation

Electrolyte‐Gated Synaptic Transistor with Oxygen Ions

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Product

Resources

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Configurable Resistive Response in BaTiO₃ Ferroelectric Memristors via Electron Beam Radiation