Universal memory based on phase-change materials: From phase-change random access memory to optoelectronic hybrid storage*

Liu, Bo; Wei, Tao; Hu, Jing; Li, Wanfei; Ling, Yun; Liu, Qianqian; Cheng, Miao; Zhang, Song

doi:10.1088/1674-1056/abeedf

Cited by 18 publications

(7 citation statements)

References 339 publications

(372 reference statements)

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“…[40][41][42][43][44][45] The PCM operations, based on the reversible switching between the crystallized state and the disordered amorphous state of a chalcogenide alloy (typically a telluride), exhibit a marked contrast in the electrical conductivity and optical reflectivity, and are ultra-rapid, on the several ten-nanosecond timescales. [46][47][48][49][50][51] Moreover, experiments have revealed that the "priming" of crystalline nuclei in the amorphous state, which is denoted as the primed state, can lead to ultra-rapid set (crystallization) operations. [52][53][54] The primed state can be distinguished from the amorphous state with regard to their altered responses to thermal or electric stimuli, although a negligible variation occurs in the electrical conductance.…”

Section: Resultsmentioning

confidence: 99%

Toward Memristive Phase‐Change Neural Network with High‐Quality Ultra‐Effective Highly‐Self‐Adjustable Online Learning

Lim,

Go,

Tan

et al. 2024

Advanced Physics Research

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Memristive hardware with reconfigurable conductance levels are leading candidates for achieving artificial neural networks (ANNs). However, owing to difficulties in device character design and circuit combination, the ability to perform complicated online‐learning tasks on a memristive network is not well understood. Here, tandem (T) material states are harnessed in a phase‐change memory (PCM) element, i.e., the primed‐amorphous state and the partial‐crystallized state, by utilizing an impetus‐and‐consequent pair pulse through a large degree of configurational ordering, and illustrate the development of an integrated system for achieving in‐memory computing and neural networks (NNs). A correct classification of 96.1% of 10,000 separate test images from the conventional Modified‐National‐Institute‐of‐Standards‐and‐Technology (MNIST) database in the tandem neural‐network (T‐NN) model is achieved, as well as image recognition for 28×28‐pixel pictures. The T‐NN configuration exhibits an in situ learning, with 50% of the elements stuck in the low‐conductance state, and at the same time, maintains an identification accuracy of ≈90%. The structural origin of the large degree of configurational‐ordering‐enhanced improvement in the extent of the conductance uniformity in the T‐based memristive element is revealed by theoretical studies. This work opens the door for attaining a widely relevant hardware system capable of performing artificial intelligence tasks with a large power‐time efficacy.

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Section: Resultsmentioning

confidence: 99%

Toward Memristive Phase‐Change Neural Network with High‐Quality Ultra‐Effective Highly‐Self‐Adjustable Online Learning

Lim,

Go,

Tan

et al. 2024

Advanced Physics Research

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“…[194,210,211] Apart from the abovementioned resistive memristors based on ionic conductors and metal oxides, memristors composed of phase change materials (PCM) have also become the topic of intense investigations in recent years. [212][213][214][215] Analogous to the resistance variation controlled by the filament path in resistive memristors, the tuned amorphous and crystalline states can enable large resistance contrast in PCM memristors. [216,217] The nonvolatile memory based on PCM is particularly suitable for mapping analog synaptic weights due to the continuously variable conductance of the PCM.…”

Section: (13 Of 22)mentioning

confidence: 99%

Bio‐Inspired 3D Artificial Neuromorphic Circuits

Liu

Wang

et al. 2022

Adv Funct Materials

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Neuromorphic circuits emulating the bio‐brain functionality via artificial devices have achieved a substantial scientific leap in the past decade. However, even with the advent of highly advanced bio‐inspired algorithms, the artificial intelligence based on current neuromorphic circuits is lagging behind significantly when compared with naturally evolved biological neural circuits. This massive and intriguing discrepancy is partly due to the incomprehensive understanding of bio‐brain operating mechanism, which relies heavily on the extremely complexed entangled 3D hierarchical neural networks. Configuring 3D neuromorphic hardware with combined computing and memory functionalities, coupled with compatible progress of software algorithms, can be an inevitable route to surmount the limitation encountered by current 2D artificial circuits. Herein, referring to the neuron configuration in 3D perspective together with detailed signal generation and propagation mechanism, the von Neumann configuration is compared with state‐of‐the‐art in‐memory computing architecture, and the development and perspectives of 3D in‐memory computing neuromorphic circuits are highlighted.

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“…While nonvolatile flash memories encounter charge storage problems originating from their fundamental scaling limits, which hinder their implementation on further size miniaturization . To overcome the bottleneck, enormous emerging nonvolatile memories, such as phase change random access memory, magnetoresistive RAM, and resistive RAM (RRAM) are viewed as the next promising candidates or alternatives by their excellent memory performance and requirements. Among them, RRAMs exhibit lots of benefits, including low fabrication cost, a simple metal–insulator–metal (MIM) structure, complementary metal–oxide–semiconductor compatibility, small effective cell size of 4 F 2 , fast switching speed, high cycling endurance, and favorable retention time. − Transition metal oxide RRAMs such as HfO 2 , , TiO 2 , , NiO, , and ZnO , have been extensively studied and researched.…”

Section: Introductionmentioning

confidence: 99%

Investigation of Different Oxygen Partial Pressures on MgGa₂O₄-Resistive Random-Access Memory

et al. 2023

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Different oxygen partial-pressure MgGa2O4-resistive RAMs (RRAMs) are fabricated to investigate the resistive switching behaviors. The X-ray photoelectron spectroscopy results, set voltage, reset voltage, cycling endurance, and retention time are drawn for comparison. With the increasing oxygen ratio gas flow, the resistive switching characteristics of MgGa2O4 RRAM are drastically elevated by changing the fabrication conditions of the RS layer. Moreover, we portray a filament model to explain the most likely mechanism associated with the generation and rupture of conductive filaments composed of oxygen vacancies. The formation of the interfacial layer (AlO x ) and the participation of the Joule heating effect are included to explain the highly distributed high-resistance state (HRS). The high randomness among switching cycles for memory application should be prevented, but it is suitable for the physical unclonable function. The relationship between HRS and the next time set voltage shows a strong correlation, and the conduction mechanisms of the low-resistance state (LRS) and HRS correspond to ohmic conduction and space charge-limited conduction, respectively. Meanwhile, the RRAM undergoes 10,000 s retention tests, and the two resistance states can be distinguished without obvious alternation or degradation. A favorable cycling endurance and retention time achieved by optimizing the fabrication parameters of Al/MgGa2O4/Pt RRAM have the potential for nonvolatile memristors and information security applications.

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Universal memory based on phase-change materials: From phase-change random access memory to optoelectronic hybrid storage*

Cited by 18 publications

References 339 publications

Toward Memristive Phase‐Change Neural Network with High‐Quality Ultra‐Effective Highly‐Self‐Adjustable Online Learning

Toward Memristive Phase‐Change Neural Network with High‐Quality Ultra‐Effective Highly‐Self‐Adjustable Online Learning

Bio‐Inspired 3D Artificial Neuromorphic Circuits

Investigation of Different Oxygen Partial Pressures on MgGa₂O₄-Resistive Random-Access Memory

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Universal memory based on phase-change materials: From phase-change random access memory to optoelectronic hybrid storage*

Cited by 18 publications

References 339 publications

Toward Memristive Phase‐Change Neural Network with High‐Quality Ultra‐Effective Highly‐Self‐Adjustable Online Learning

Toward Memristive Phase‐Change Neural Network with High‐Quality Ultra‐Effective Highly‐Self‐Adjustable Online Learning

Bio‐Inspired 3D Artificial Neuromorphic Circuits

Investigation of Different Oxygen Partial Pressures on MgGa2O4-Resistive Random-Access Memory

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Investigation of Different Oxygen Partial Pressures on MgGa₂O₄-Resistive Random-Access Memory