Memristive Behavior Enabled by Amorphous–Crystalline 2D Oxide Heterostructure

Yin, Xin; Wang, Yizhan; Chang, Tzu‐Hsuan; Zhang, Pei; Li, Jun; Xue, Panpan; Long, Yin; Shohet, J. L.; Voyles, Paul M.; Ma, Zhenqiang; Wang, Xudong

doi:10.1002/adma.202000801

Cited by 31 publications

(33 citation statements)

References 56 publications

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“…Multilayer dielectrics are the subject of research by many authors [18,39,105]. The addition of an additional layer promotes the formation of a vacancy reservoir, and its thickness and composition affect the size of the specified reservoir and the migration and formation energies of vacancies.…”

Section: Active Dielectric Layer Structure and Thicknessmentioning

confidence: 99%

To the Issue of the Memristor’s HRS and LRS States Degradation and Data Retention Time

Фадеев

Руденко

2021

Russ Microelectron

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In this review of experimental studies, the retention time and endurance of memristor RRAM memory elements based on reversible resistive switching in oxide dielectrics are studied. The influence of external parameters—switching pulses and ambient temperature—as well as internal factors—evolution of the concentration of oxygen vacancies in the filament region, the material, structure; the thickness of the active dielectric layer, material of metal electrodes on the long-term stability of high resistance state (HRS) and the low resistance state (LRS) of the memristor is discussed.

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Section: Active Dielectric Layer Structure and Thicknessmentioning

confidence: 99%

To the Issue of the Memristor’s HRS and LRS States Degradation and Data Retention Time

Фадеев

Руденко

2021

Russ Microelectron

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“…In the last two sections, we have already seen examples of how advanced technologies enable electronic mimics of individual parts of the neural system with demonstrated simple computational functionalities. We do not intend to survey the neuromorphic hardware implementation again as this has been done in numerous reviews, just to name a few, at materials level, [ 48,661–722 ] at device level, [ 10,244,263,723–790 ] at more circuit level, or above. [ …”

Section: Implementation Levelmentioning

confidence: 99%

A Marr's Three‐Level Analytical Framework for Neuromorphic Electronic Systems

Guo

Zou

et al. 2021

Advanced Intelligent Systems

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Neuromorphic electronics, an emerging field that aims for building electronic mimics of the biological brain, holds promise for reshaping the frontiers of information technology and enabling a more intelligent and efficient computing paradigm. As their biological brain counterpart, the neuromorphic electronic systems are complex, having multiple levels of organization. Inspired by David Marr's famous three‐level analytical framework developed for neuroscience, the advances in neuromorphic electronic systems are selectively surveyed and given significance to these research endeavors as appropriate from the computational level, algorithmic level, or implementation level. Under this framework, the problem of how to build a neuromorphic electronic system is defined in a tractable way. In conclusion, the development of neuromorphic electronic systems confronts a similar challenge to the one neuroscience confronts, that is, the limited constructability of the low‐level knowledge (implementations and algorithms) to achieve high‐level brain‐like (human‐level) computational functions. An opportunity arises from the communication among different levels and their codesign. Neuroscience lab‐on‐neuromorphic chip platforms offer additional opportunity for mutual benefit between the two disciplines.

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“…[22] The MoS 2 /Sb 2 O 3 FETs exhibited an ultrahigh on/off ratio of 10 8 , enhanced carrier mobility of 145 cm 2 V À1 s À1 (compared with 26 cm 2 V À1 s À1 for the same device on SiO 2 ), and ideal subthreshold swing of 64 mV dec À1 . In addition, 2D oxides have also shown application potential in piezoelectric transistors, [23] artificial synaptic devices, [24,25] memristors, [26] and anisotropic detection. [27,28] At present, more 2D oxides have been reported, the synthesis methods are emerging constantly, and their application in the electronics and optoelectronics is increasingly extensive.…”

Section: Introductionmentioning

confidence: 99%

2D Oxides for Electronics and Optoelectronics

Liu

Cai³

et al. 2022

Small Science

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In recent years, 2D oxides have attracted considerable attention due to their novel physical properties and excellent stability. With the efforts of researchers, significant progress has been made in the synthesis and electronics and optoelectronics application of 2D oxides. Herein, a systematic review focusing on the preparation of 2D oxides and their applications in electronics and optoelectronics is provided. First, 2D oxides are summarized and classified according to their elements. Then, common preparation methods to synthesize 2D oxides including exfoliation, liquid‐phase synthesis, vapor deposition, surface oxidation of metal, and so on are introduced. Further, the applications of 2D oxides in electronics and optoelectronics are presented. Finally, the current challenges and envisioned development of 2D oxides are commented and prospected.

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Memristive Behavior Enabled by Amorphous–Crystalline 2D Oxide Heterostructure

Cited by 31 publications

References 56 publications

To the Issue of the Memristor’s HRS and LRS States Degradation and Data Retention Time

To the Issue of the Memristor’s HRS and LRS States Degradation and Data Retention Time

A Marr's Three‐Level Analytical Framework for Neuromorphic Electronic Systems

2D Oxides for Electronics and Optoelectronics

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