Redox gated polymer memristive processing memory unit

Zhang, Bin; Fan, Fei; Xue, Wei; Liu, Gang; Fu, Yubin; Zhuang, Xiaodong; Xu, Xin; Gu, Junwei; Li, Run-Wei; Chen, Yu

doi:10.1038/s41467-019-08642-y

Cited by 106 publications

(92 citation statements)

References 63 publications

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“…The oxidation is reversible, with most of the charged PQT along the SD line reduced back to neutral PQT upon reversal of the bias to V SG = −2 V. This observation provides a direct correlation of polaron generation with device conductivity. Zhang et al [77] investigated the spatial evolution of the oxidative states of the ferrocene pendant triphenylamine (TPA) and ferrocene (Fc) (PFTPA-Fc) thin film under different applied voltages through fluorescence line scans. Strong emission appeared in the wavelength range of 410-460 nm in initial state with emissions between 430 and 460 nm and between 415 and 430 nm corresponding to Fc and TPA, respectively (Figure 9c).…”

Section: Switching Mechanisms In Organic Devicesmentioning

confidence: 99%

“…Not like showing in the Pt/Ta 2 O 5 /Pt device (Figure 11f), Ta metal can be oxidized spontaneously, which can produce a hazy interface between the cathode and Ta 2 O 5 film as a load resistor to inhibit the overgrowth of nanofilaments. Furthermore, Xue et al [77] found the forming voltages of the switching devices strongly depend on the roughness of the interface between electrode and switching layer. The smaller forming voltage/free forming process can be obtained in memristors with rougher interface (Figure 11h) [77].…”

Section: Interface Engineeringmentioning

confidence: 99%

“…Furthermore, Xue et al [77] found the forming voltages of the switching devices strongly depend on the roughness of the interface between electrode and switching layer. The smaller forming voltage/free forming process can be obtained in memristors with rougher interface (Figure 11h) [77]. Furthermore, if the rough interfaces are introduced with a controllable manner such as by using lithography, the device performance will be greatly improved without introducing complex device integration.…”

Section: Interface Engineeringmentioning

confidence: 99%

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Solid-State Electrochemical Process and Performance Optimization of Memristive Materials and Devices

Xue

Liu

2019

Chemistry

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As an emerging technology, memristors are nanoionic-based electrochemical systems that retains their resistance state based on the history of the applied voltage/current. They can be used for on-chip memory and storage, biologically inspired computing, and in-memory computing. However, the underlying physicochemical processes of memristors still need deeper understanding for the optimization of the device properties to meet the practical application requirements. Herein, we review recent progress in understanding the memristive mechanisms and influential factors for the optimization of memristive switching performances. We first describe the working mechanisms of memristors, including the dynamic processes of active metal ions, native oxygen ions and other active ions in ECM cells, VCM devices and ion gel-based devices, and the switching mechanisms in organic devices, along with discussions on the influential factors of the device performances. The optimization of device properties by electrode/interface engineering, types/configurations of dielectric materials and bias scheme is then illustrated. Finally, we discuss the current challenges and the future development of the memristor.

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Section: Switching Mechanisms In Organic Devicesmentioning

confidence: 99%

Section: Interface Engineeringmentioning

confidence: 99%

Section: Interface Engineeringmentioning

confidence: 99%

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Solid-State Electrochemical Process and Performance Optimization of Memristive Materials and Devices

Xue

Liu

2019

Chemistry

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“…The high resistance state (HRS) can be regarded as “0” bit in data storage, and thus the switching from HRS to the low resistance state (LRS) is equivalent to “0”‐to‐“1” binary conversion. Based on this concept, multibit storage (eg, “0,” “1,” “2”) can be expected when more than two resistance states of one material are acquired under the electric field, 16‐18 which contributes to exponentially increase the storage capacity within one memory cell.…”

Section: Introductionmentioning

confidence: 99%

Recent advances in organic‐based materials for resistive memory applications

Qian

Zhu

et al. 2020

InfoMat

137

140

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With the rapid development of data‐driven human interaction, advanced data‐storage technologies with lower power consumption, larger storage capacity, faster switching speed, and higher integration density have become the goals of future memory electronics. Nevertheless, the physical limitations of conventional Si‐based binary storage systems lag far behind the ultrahigh‐density requirements of post‐Moore information storage. In this regard, the pursuit of alternatives and/or supplements to the existing storage technology has come to the forefront. Recently, organic‐based resistive memory materials have emerged as promising candidates for next‐generation information storage applications, which provide new possibilities of realizing high‐performance organic electronics. Herein, the memory device structure, switching types, mechanisms, and recent advances in organic resistive memory materials are reviewed. In particular, their potential of fulfilling multilevel storage is summarized. Besides, the present challenges and future prospects confronted by organic resistive memory materials and devices are discussed.

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“…Proposals for computers that exploit chemical processes have taken one or both of two broad approaches: 1) using chemistry and biochemistry to emulate circuit components or cellular automata, and 2) employing a large number of molecules to explore a combinatorial space in parallel. Examples for the first include reaction-diffusion systems (7), Belousov-Zhabotinsky oscillatory reaction (8), memristive polymers (9), and transcription regulation for cellular signaling (10,11), and other chemical and biochemical analogues of logic gates (12,13). In the second category of parallelized computing, we find microfluidic devices (14), nanofabricated networks (15)(16)(17), and adaptive amoebal networks (18).…”

Section: Introductionmentioning

confidence: 99%

A Molecular Computing Approach to Solving Optimization Problems via Programmable Microdroplet Arrays

Guo¹,

Friederich²,

Cao³

et al. 2019

Preprint

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The search for novel forms of computing that show advantages as alternatives to the dominant von-Neuman model-based computing is important as it will enable different classes of problems to be solved. By using droplets and room-temperature processes, molecular computing is a promising research direction with potential biocompatibility and cost advantages. In this work, we present a new approach for computation using a network of chemical reactions taking place within an array of spatially localized droplets whose contents represent bits of information. Combinatorial optimization problems are mapped to an Ising Hamiltonian and encoded in the form of intra- and inter- droplet interactions. The problem is solved by initiating the chemical reactions within the droplets and allowing the system to reach a steady-state; in effect, we are annealing the effective spin system to its ground state. We propose two implementations of the idea, which we ordered in terms of increasing complexity. First, we introduce a hybrid classical-molecular computer where droplet properties are measured and fed into a classical computer. Based on the given optimization problem, the classical computer then directs further reactions via optical or electrochemical inputs. A simulated model of the hybrid classical-molecular computer is used to solve boolean satisfiability and a lattice protein model. Second, we propose architectures for purely molecular computers that rely on pre-programmed nearest-neighbour inter-droplet communication via energy or mass transfer.

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Redox gated polymer memristive processing memory unit

Cited by 106 publications

References 63 publications

Solid-State Electrochemical Process and Performance Optimization of Memristive Materials and Devices

Solid-State Electrochemical Process and Performance Optimization of Memristive Materials and Devices

Recent advances in organic‐based materials for resistive memory applications

A Molecular Computing Approach to Solving Optimization Problems via Programmable Microdroplet Arrays

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