Ultralow Set Voltage and Enhanced Switching Reliability for Resistive Random-Access Memory Enabled by an Electrodeposited Nanocone Array

Xue, Qi; Peng, Yan; Cao, Liang; Xia, Yuanyuan; Liang, Jianghu; Chen, Chun‐Chao; Li, Ming; Hang, Tao

doi:10.1021/acsami.2c03978

Cited by 12 publications

(10 citation statements)

References 50 publications

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“…With the development of non‐volatile flash memory devices, there have been extensive studies on next‐generation, non‐volatile RAM devices for faster computing and memory applications. Such non‐volatile memory devices include magneto‐resistive RAM (MRAM), [ 12,13 ] resistive RAM (RRAM), [ 14,15 ] phase‐change RAM (PRAM), [ 16,17 ] and ferroelectric RAM (FeRAM). [ 18,19 ]…”

Section: Fundamentalsmentioning

confidence: 99%

“…With the development of nonvolatile flash memory devices, there have been extensive studies on next-generation, non-volatile RAM devices for faster computing and memory applications. Such non-volatile memory devices include magneto-resistive RAM (MRAM), [12,13] resistive RAM (RRAM), [14,15] phase-change RAM (PRAM), [16,17] and ferroelectric RAM (FeRAM). [18,19] In this review, we will mainly discuss memory and synaptic devices based on emerging 2D layered ferroelectric materials, beyond silicon-based volatile RAM devices.…”

Section: Memory Device Applications Of Ferroelectric Materialsmentioning

confidence: 99%

“…[7][8][9][10][11] The primary candidates for nextgeneration memory devices are based on the type of switching mechanism, considering the materials' magnetic, resistive and phase-change, or ferroelectric features. [12][13][14][15][16][17][18][19] The switching characteristics of conventional 3D materials have been actively investigated, but the fabrication cost and fine engineering required for the device performance still remain critical issues with such 3D materials. Since the discovery of graphene, atomically thin 2D [20][21][22] and 1D [23] materials have emerged as new candidates for future memory devices.…”

Section: Introductionmentioning

confidence: 99%

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Memory and Synaptic Devices Based on Emerging 2D Ferroelectricity

Joo

Hwang

Hong

et al. 2023

Adv Elect Materials

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Memory devices are an essential part of modern electronics. Efforts to move beyond the traditional "read" and "write" of digital information in volatile and non-volatile memory devices are leading to the rapid growth of neuromorphic technology. There is a growing demand for memory devices with continuous memory states with various retention times and greater integration density with more energy-efficient mechanisms. Two types of memory devices (i.e., non-volatile digital memory and neuro-synaptic devices) have been extensively investigated with emerging materials. Among numerous materials for such memory devices, in this review, the authors focus on 2D ferroelectric materials for promising memory and synaptic devices. Three types of memory devices based on 2D ferroelectric materials are classified and discussed here: 1) ferroelectric gating of semiconducting channels, 2) active ferroelectric channels, and 3) ferroelectric tunnel junction devices. It is known that atomically thin geometry competes with ferroelectricity, which can degrade the quality of the devices based on atomically thin ferroelectric materials. Various efforts to resolve the fundamental issue with emerging 2D ferroelectric materials and how they can be used as a critical element for memory and synaptic devices are surveyed.

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Section: Fundamentalsmentioning

confidence: 99%

Section: Memory Device Applications Of Ferroelectric Materialsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Memory and Synaptic Devices Based on Emerging 2D Ferroelectricity

Joo

Hwang

Hong

et al. 2023

Adv Elect Materials

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“…promising candidate for artificial synapses due to its variable conductance similar to the change of synaptic weight as well as its fast switching speed, low power consumption, and high-density stacking. [12][13][14][15] The conductance of memristive devices can be dynamically modulated in response to a variety of external stimuli, such as electric, [12,13] magnetic, [16,17] humidity, [18,19] or photo-illumination. [20][21][22][23] Among these stimuli, optical signal possesses the advantages of low power consumption, wide bandwidth, and low crosstalk, which is of great significance for the construction of an efficient brain-like computing network.…”

Section: Introductionmentioning

confidence: 99%

Multi‐Wavelength‐Recognizable Memristive Devices via Surface Plasmon Resonance Effect for Color Visual System

Han

Shan

Lin

et al. 2023

Small

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Photoelectric memristor has attracted many attentions thanks to their promising potential in optical communication chips and artificial vision systems. However, the implementation of an artificial visual system based on memristive devices remains a considerable challenge because most photoelectric memristors cannot recognize color. Herein, multi‐wavelength recognizable memristive devices based on silver(Ag) nanoparticles (NPs) and porous silicon oxide (SiOx) nanocomposites are presented. Rely on the effects of localized surface plasmon resonance (LSPR) and optical excitation of Ag NPs in SiOx, the set voltage of the device can be gradually reduced. Moreover, the current overshoot problem is alleviated to suppress conducting filament overgrowth after visible light irradiation with different wavelengths, resulting in diverse low resistance states (LRS). Taking advantage of the characteristics of controlled switching voltage and LRS resistance distribution, color image recognition is finally realized in the present work. X‐ray photoelectron spectroscopy (XPS) and conductive atomic force microscopy (C‐AFM) show that the light irradiation plays an important role on resistive switching (RS) process: the photo‐assisted Ag ionization leads to a significant reduction of set voltage and overshoot current. This work provides an effective method toward the development of multi‐wavelength‐recognizable memristive devices for future artificial color vision system.

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“…Recent works have been reported to address the challenges, but few have addressed the stochasticity of the memristors in a logic gate despite the requirement of strict control for the logic cascading. [14][15][16] For instance, three cascaded two-input NOR gates with a bit-error-rate (BER) of 7% result in an increment in the BER to 20% ((1-0.93 3 ) Â 100). In other words, a higher control in stochasticity of the single-logic operation is required as the number of cascaded logic gates increases for the complex logic operation.…”

Section: Introductionmentioning

confidence: 99%

Efficient Method for Error Detection and Correction in In‐Memory Computing Based on Reliable Ex‐Logic Gates

Park

Kim

Shin

et al. 2023

Advanced Intelligent Systems

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In‐memory computing using memristor‐based stateful logic reveals high efficiency in the computing paradigm where the memory and computation are colocated. Still, variations in the memristor induce reliability issues for practical applications. Previous error detection and correction modules in the inmemory logic gates can handle the errors but only account for nonswitching errors of the output memristor, while the highly probable switching error of the output memristor is neglected, reducing overall efficiency. Moreover, the module operations use other added stateful logic gates, which may add errors. Herein, modules to handle both nonswitching and switching error cases within the three average steps using reliable logic gates consisting of five memristors are proposed. Detecting both error cases allows logic gates to be still operated in the optimized region for high‐energy efficiency and stability. In addition, combining two different logic families of stateful and sequential logic gates provides the reliability of the stateful logic gates and a possible solution to the peripheral complexity of cascading sequential logic gates. Although detection and correction are demonstrated in NOR and NAND logic gates with the memristor model, the other logic gates can be applied with the same algorithm with the appropriate module‐enable signal and input‐checker bits.

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Ultralow Set Voltage and Enhanced Switching Reliability for Resistive Random-Access Memory Enabled by an Electrodeposited Nanocone Array

Cited by 12 publications

References 50 publications

Memory and Synaptic Devices Based on Emerging 2D Ferroelectricity

Memory and Synaptic Devices Based on Emerging 2D Ferroelectricity

Multi‐Wavelength‐Recognizable Memristive Devices via Surface Plasmon Resonance Effect for Color Visual System

Efficient Method for Error Detection and Correction in In‐Memory Computing Based on Reliable Ex‐Logic Gates

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