Proton-Assisted Redox-Based Three-Terminal Memristor for Synaptic Device Applications

Liu, Lingli; Dananjaya, Putu Andhita; Chee, Mun Yin; Lim, Gerard Joseph; Lee, Calvin Xiu Xian; Lew, Wen Siang

doi:10.1021/acsami.3c03974

Cited by 9 publications

(5 citation statements)

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“…The effectiveness of using a p-Ti 3 C 2 T x -based memristor as an artificial synapse was assessed in a four-layer neural network designed for pattern recognition simulation. The neural network comprised an input layer with 784 neurons, two hidden layers with 250 and 125 neurons, respectively, and an output layer with 10 neurons, all interconnected by synapses (Figure a) . The input data for training and testing consisted of handwritten digits (ranging from 0 to 9) from the Modified National Institute of Standards and Technology (MNIST) database, with each digit represented by a 28 × 28 pixels image.…”

Section: Resultsmentioning

confidence: 99%

“…The neural network comprised an input layer with 784 neurons, two hidden layers with 250 and 125 neurons, respectively, and an output layer with 10 neurons, all interconnected by synapses (Figure 7a). 59 The input data for training and testing consisted of handwritten digits (ranging from 0 to 9) from the Modified National Institute of Standards and Technology (MNIST) database, with each digit represented by a 28 × 28 pixels image. The memristor's behavior, in terms of linearity, dynamic range, and precision during the potentiation and depression processes (Figure 4d), played a crucial role in updating the synaptic weights during the training phase.…”

Section: ( ) Ppf Index 100%mentioning

confidence: 99%

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Control-Etched Ti₃C₂T_x MXene Nanosheets for a Low-Voltage-Operating Flexible Memristor for Efficient Neuromorphic Computation

Gosai,

Patel,

Liu

et al. 2024

ACS Appl. Mater. Interfaces

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Hardware neural networks with mechanical flexibility are promising next-generation computing systems for smart wearable electronics. Overcoming the challenge of developing a fully synaptic plastic network, we demonstrate a low-operating-voltage PET/ITO/p-MXene/Ag flexible memristor device by controlling the etching of aluminum metal ions in Ti3C2T x MXene. The presence of a small fraction of Al ions in partially etched MXene (p-Ti3C2T x ) significantly suppresses the operating voltage to 1 V compared to 7 V from fully Al etched MXene (f-Ti3C2T x )-based devices. Former devices exhibit excellent non-volatile data storage properties, with a robust ∼103 ON/OFF ratio, high endurance of ∼104 cycles, multilevel resistance states, and long data retention measured up to ∼106 s. High mechanical stability up to ∼73° bending angle and environmental robustness are confirmed with consistent switching characteristics under increasing temperature and humid conditions. Furthermore, a p-Ti3C2T x MXene memristor is employed to mimic the biological synapse by measuring the learning–forgetting pattern for ∼104 cycles as potentiation and depression. Spike time-dependent plasticity (STDP) based on Hebb’s Learning rules is also successfully demonstrated. Moreover, a remarkable accuracy of ∼95% in recognizing modified patterns from the National Institute of Standards and Technology (MNIST) data set with just 29 training epochs is achieved in simulation. Ultimately, our findings underscore the potential of MXene-based flexible memristor devices as versatile components for data storage and neuromorphic computing.

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Section: Resultsmentioning

confidence: 99%

Section: ( ) Ppf Index 100%mentioning

confidence: 99%

Control-Etched Ti₃C₂T_x MXene Nanosheets for a Low-Voltage-Operating Flexible Memristor for Efficient Neuromorphic Computation

Gosai,

Patel,

Liu

et al. 2024

ACS Appl. Mater. Interfaces

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“…11,12 Concurrently, non-filamentary memristors have also been explored in neuromorphic research. [13][14][15] The analog nature of such memristive devices, due to their gradual resistive switching characteristics, aligns well with the intricacies of the human brain, allowing for the creation of artificial neural networks that closely mimic the behavior of biological synapses. The synaptic weights, also known as the connection strength between the neurons, are represented by the conductance of each device, and the analog properties enable different weights to be stored via a step-by-step weight adjustment during the neural network training process.…”

Section: Nanoscale Horizonsmentioning

confidence: 99%

Unraveling the origins of the coexisting localized-interfacial mechanism in oxide-based memristors in CMOS-integrated synaptic device implementations

Koh,

Dananjaya,

Poh

et al. 2024

Nanoscale Horiz.

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“…There is also a natural biological context to consider protons for neuromorphic computing owing to their important role in the animal brain. Protons can be inserted or extracted into the channel layers, or stored in solid or liquid/gel electrolytes to develop three-terminal memory devices, and also induce nonvolatile resistance change in two-terminal memristor devices. − Finally, proton-conducting materials present nonvolatile memory and rich biomimetic properties, offering an appealing path to neuromorphic hardware and efficient implementations of neuromorphic artificial intelligence since the intercalation and movement of protons as a charge carrier other than electrons provides a new knob for tuning the electrical properties of a material. ,− …”

Section: Introductionmentioning

confidence: 99%

Proton Conducting Neuromorphic Materials and Devices

Yuan,

Patel,

Banik

et al. 2024

Chem. Rev.

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Neuromorphic computing and artificial intelligence hardware generally aims to emulate features found in biological neural circuit components and to enable the development of energy-efficient machines. In the biological brain, ionic currents and temporal concentration gradients control information flow and storage. It is therefore of interest to examine materials and devices for neuromorphic computing wherein ionic and electronic currents can propagate. Protons being mobile under an external electric field offers a compelling avenue for facilitating biological functionalities in artificial synapses and neurons. In this review, we first highlight the interesting biological analog of protons as neurotransmitters in various animals. We then discuss the experimental approaches and mechanisms of proton doping in various classes of inorganic and organic proton-conducting materials for the advancement of neuromorphic architectures. Since hydrogen is among the lightest of elements, characterization in a solid matrix requires advanced techniques. We review powerful synchrotronbased spectroscopic techniques for characterizing hydrogen doping in various materials as well as complementary scattering techniques to detect hydrogen. First-principles calculations are then discussed as they help provide an understanding of proton migration and electronic structure modification. Outstanding scientific challenges to further our understanding of proton doping and its use in emerging neuromorphic electronics are pointed out.

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Proton-Assisted Redox-Based Three-Terminal Memristor for Synaptic Device Applications

Cited by 9 publications

References 50 publications

Control-Etched Ti₃C₂T_x MXene Nanosheets for a Low-Voltage-Operating Flexible Memristor for Efficient Neuromorphic Computation

Control-Etched Ti₃C₂T_x MXene Nanosheets for a Low-Voltage-Operating Flexible Memristor for Efficient Neuromorphic Computation

Unraveling the origins of the coexisting localized-interfacial mechanism in oxide-based memristors in CMOS-integrated synaptic device implementations

Proton Conducting Neuromorphic Materials and Devices

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Proton-Assisted Redox-Based Three-Terminal Memristor for Synaptic Device Applications

Cited by 9 publications

References 50 publications

Control-Etched Ti3C2Tx MXene Nanosheets for a Low-Voltage-Operating Flexible Memristor for Efficient Neuromorphic Computation

Control-Etched Ti3C2Tx MXene Nanosheets for a Low-Voltage-Operating Flexible Memristor for Efficient Neuromorphic Computation

Unraveling the origins of the coexisting localized-interfacial mechanism in oxide-based memristors in CMOS-integrated synaptic device implementations

Proton Conducting Neuromorphic Materials and Devices

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Product

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Control-Etched Ti₃C₂T_x MXene Nanosheets for a Low-Voltage-Operating Flexible Memristor for Efficient Neuromorphic Computation

Control-Etched Ti₃C₂T_x MXene Nanosheets for a Low-Voltage-Operating Flexible Memristor for Efficient Neuromorphic Computation