Memory materials and devices: From concept to application

Zhang, Zhenhan; Wang, Zongwei; Shi, Tao; Bi, Chong; Rao, Feng; Cai, Yimao; Liu, Qi; Wu, Huaqiang; Zhou, Peng

doi:10.1002/inf2.12077

Cited by 194 publications

(139 citation statements)

References 177 publications

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“…[16] The use of 2D van der Waals (vdW) structures in synaptic devices for neuromorphic computing has provoked considerable interest because of the intriguing physical and chemical properties of these structures associated with their strictly defined low dimensionalities, [42,65] including their large surface-to-volume ratios, [33,66] dangling-bond-free surfaces, [65,67,68] and highly gatetunable bandgaps. [69][70][71][72] A variety of layered crystals, including MoO 3 , MoS 2 , WS 2 , and WSe 2 , can emulate both STP and LTP effectively. Zhu et al [33] demonstrated nanoscale synaptic transistors based on a vdW heterostructure that was composed of TMDs and phosphorus trichalcogenides.…”

Section: Electric-double-layer Effectmentioning

confidence: 99%

Stimuli‐Enabled Artificial Synapses for Neuromorphic Perception: Progress and Perspectives

Pan

Jin

Gao

et al. 2020

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Brain‐inspired neuromorphic computing is intended to provide effective emulation of the functionality of the human brain via the integration of electronic components. Recent studies of synaptic plasticity, which represents one of the most significant neurochemical bases of learning and memory, have enhanced the general comprehension of how the brain functions and have thereby eased the development of artificial neuromorphic devices. An understanding of the synaptic plasticity induced by various types of stimuli is essential for neuromorphic system construction. The realization of multiple stimuli‐enabled synapses will be important for future neuromorphic computing applications. In this Review, state‐of‐the‐art synaptic devices with particular emphasis on their synaptic behaviors under excitation by a variety of external stimuli are summarized, including electric fields, light, magnetic fields, pressure, and temperature. The switching mechanisms of these synaptic devices are discussed in detail, including ion migration, electron/hole transfer, phase transition, redox‐based resistive switching, and other mechanisms. This Review aims to provide a comprehensive understanding of the operating mechanisms of artificial synapses and thus provides the principles required for design of multifunctional neuromorphic systems with parallel processing capabilities.

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Section: Electric-double-layer Effectmentioning

confidence: 99%

Stimuli‐Enabled Artificial Synapses for Neuromorphic Perception: Progress and Perspectives

Pan

Jin

Gao

et al. 2020

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“…22 2D layered semiconductors with atomic thickness possess the potential for continuous shrinking, [23][24][25] which is a promising candidate for future high-density memory and computing systems. 26,27 Particularly, 2D layered α-In2Se3 exhibits robust ferroelectricity at room temperature (RT) without annealing, 14,28,29 and thanks to the intrinsic interlocking of dipoles in α-In2Se3, 18,22 it can maintain ferroelectric polarization even at atomic scale.…”

Section: Abstract: 2d α-In2se3 Ferroelectric Channel Non-volatile Mmentioning

confidence: 99%

Two-dimensional ferroelectric channel transistors integrating ultra-fast memory and neural computing

Wang

Liu

Gan

et al. 2020

Preprint

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With the advent of big data era, applications are more data-centric, and energy efficiency issues caused by frequent data interactions due to the physical separation of memory and computing will become more severe. Emerging technologies have been proposed to perform analog computing with memory to address the dilemma. Ferroelectric memory has become a promising technology due to field-driven fast switching and non-destructive readout, but endurance and miniaturization are limited. Here, we demonstrate the α-In2Se3 ferroelectric semiconductor channel device that integrates non-volatile memory (NVM) and neural computation functions. Remarkable performance includes NVM ultra-fast write speed of 40ns, improved endurance through internal electric field, flexible adjustment of neural plasticity, energy consumption as low as 40fJ per event, and thermally modulated 94.74% high-precision iris recognition classification simulation. This prototypical demonstration laid the foundation for an integrated memory computing system with high density and energy efficiency.

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“…Resembling the operating principle of human brains that transmit and process information through huge amounts of interconnected neurons and synapses [1][2][3][4], neuromorphic computing paradigm based on new solid-state electronic devices have demonstrated advantages of high efficiency, low power consumption, and parallel processing ability when handling big-data analysis tasks [5][6][7]. Plenty of research efforts have been devoted to emulating the electrical functions of biological synapses and neurons with ferroelectric, magnetic, phase-change, and resistive switching devices [8][9][10], wherein the resistive switching memristors distinguish themselves as promising post-Moore era candidates with their simple device structure, crossbar array, and 3D stacking capability for very large scale integration [11][12][13][14][15][16][17]. In particular, the ion migration and filamentary conduction mechanism make the memristor devices extremely scalable, enabling them to easily approach the lithographic limitations [18][19][20][21].…”

Section: Introductionmentioning

confidence: 99%

Improving the Recognition Accuracy of Memristive Neural Networks via Homogenized Analog Type Conductance Quantization

et al. 2020

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Conductance quantization (QC) phenomena occurring in metal oxide based memristors demonstrate great potential for high-density data storage through multilevel switching, and analog synaptic weight update for effective training of the artificial neural networks. Continuous, linear and symmetrical modulation of the device conductance is a critical issue in QC behavior of memristors. In this contribution, we employ the scanning probe microscope (SPM) assisted electrode engineering strategy to control the ion migration process to construct single conductive filaments in Pt/HfOx/Pt devices. Upon deliberate tuning and evolution of the filament, 32 half integer quantized conductance states in the 16 G0 to 0.5 G0 range with enhanced distribution uniformity was achieved. Simulation results revealed that the numbers of the available QC states and fluctuation of the conductance at each state play an important role in determining the overall performance of the neural networks. The 32-state QC behavior of the hafnium oxide device shows improved recognition accuracy approaching 90% for handwritten digits, based on analog type operation of the multilayer perception (MLP) neural network.

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Memory materials and devices: From concept to application

Cited by 194 publications

References 177 publications

Stimuli‐Enabled Artificial Synapses for Neuromorphic Perception: Progress and Perspectives

Stimuli‐Enabled Artificial Synapses for Neuromorphic Perception: Progress and Perspectives

Two-dimensional ferroelectric channel transistors integrating ultra-fast memory and neural computing

Improving the Recognition Accuracy of Memristive Neural Networks via Homogenized Analog Type Conductance Quantization

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