Reconfigurable halide perovskite nanocrystal memristors for neuromorphic computing

John, Rohit Abraham; Demirağ, Yiğit; Shynkarenko, Yevhen; Berezovska, Yuliia; Ohannessian, Natacha; Payvand, Melika; Zeng, Peng; Bodnarchuk, Maryna I.; Krumeich, Frank; Kara, Gökhan; Shorubalko, Ivan; Nair, Manu V; Cooke, G. A.; Lippert, Thomas; Indiveri, Giacomo; Kovalenko, Maksym V.

doi:10.1038/s41467-022-29727-1

Cited by 109 publications

(105 citation statements)

References 69 publications

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“…However, in order to meet the specifications of a targetted neural network, tedious fabrication processes of such memristors are required [35]. Reconfigurable memristors that employ halide perovskite nanocrystals [36] are more generalized in their application and show capability of prolonged usage of about 5, 600 cycles/updates. In comparison, the FN-synapse has a highly extensive scope of applications as the update size of any network it is employed in can be adjusted appropriately by shaping the input pulse as required.…”

Section: Discussionmentioning

confidence: 99%

On-device Synaptic Memory Consolidation using Fowler-Nordheim Quantum-tunneling

Rahman¹,

Bose²,

Chakrabartty³

2022

Preprint

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Synaptic memory consolidation has been heralded as one of the key mechanisms for supporting continual learning in neuromorphic Artificial Intelligence (AI) systems. Here we report that a Fowler-Nordheim (FN) quantum-tunneling device can implement synaptic memory consolidation similar to what can be achieved by algorithmic consolidation models like the cascade and the elastic weight consolidation (EWC) models. The proposed FN-synapse not only stores the synaptic weight but also stores the synapse's historical usage statistic on the device itself. We also show that the operation of the FN-synapse is nearoptimal in terms of the synaptic life-time and we demonstrate that a network comprising FN-synapses outperforms a comparable EWC network for a small benchmark continual learning task. With an energy foot-print of femtojoules per synaptic update, we believe that the proposed FN-synapse provides an ultra-energy-efficient approch for implementing both synaptic memory consolidation and persistent learning.

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Section: Discussionmentioning

confidence: 99%

On-device Synaptic Memory Consolidation using Fowler-Nordheim Quantum-tunneling

Rahman¹,

Bose²,

Chakrabartty³

2022

Preprint

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“…[ 5 ] For simulating synaptic behavior, several types of synaptic devices have been developed, including two‐terminal synaptic devices and three‐terminal synaptic devices. [ 6–8 ] Compared with two‐terminal devices, three‐terminal devices have the advantages of simultaneously receiving and reading stimuli, thus being one of the most promising candidates for constructing the next‐generation artificial intelligence. [ 9–11 ] Organic semiconducting materials provide the perfect platform for three‐terminal synaptic devices with the merits of being facile solution processable, mechanical flexibility, large‐area printing and favorable biocompatibility.…”

Section: Introductionmentioning

confidence: 99%

Donor Engineering Tuning the Analog Switching Range and Operational Stability of Organic Synaptic Transistors for Neuromorphic Systems

Zhao

Shen

et al. 2022

Adv Funct Materials

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Organic artificial synapses are becoming the most desirable format for neuromorphic computing due to their highly tunable resistive states. However, repressively low analog switching range, inferior memory retention, and operational instability greatly hinder the further development of organic synapses. Herein, two donor-acceptor copolymers consisting of electrondeficient isoindigo coupled with variable donating moieties for three-terminal organic synaptic transistors (TOSTs) are reported. It is found that the synaptic function and device stability of TOSTs are significantly improved by enhancing the electron-donating strength of donor units. Polymer alkylated isoindigo-bisethylenedioxythiophene exhibits high analog switching range of 170 ×, two orders of magnitude higher than that of normal organic neuromorphic devices. They also demonstrate excellent memory retention of over 5 × 10 3 s, low switching energy of 13 fJ, and ultrahigh operational stability with 99% of its original current after 100 000 write-read events in air. Furthermore, the high viability of strong donor strategy is showcased by demonstrating flexible TOSTs with stable synaptic function after repeated mechanical bending as well as organic synapses capable of simulating image information processing. Overall, this work highlights the advantages of the strong donor functionalization strategy to boost the synaptic performance and device stability of TOSTs.

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“…A memristor is a non-linear resistor with memory characteristics, and its i-v characteristic curve is related to the frequency. Its proven good performance implies significant potential in the fields of chaotic circuits [3][4][5], nonvolatile memory [6,7], digital logic [8,9], artificial neural networks [10][11][12], and non-linear circuits. In general, the research of memristors includes physical implementation [2,13,14], applications in electronic circuits [15,16], and memristor emulators [17][18][19][20][21][22][23][24][25][26].…”

Section: Introductionmentioning

confidence: 99%

Design of the Threshold-Controllable Memristor Emulator Based on NDR Characteristics

Lin

Luo

et al. 2022

Micromachines

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Due to the high manufacturing cost of memristors, an equivalent emulator has been employed as one of the mainstream approaches of memristor research. A threshold-type memristor emulator based on negative differential resistance (NDR) characteristics is proposed, with the core part being the R-HBT network composed of transistors. The advantage of the NDR-based memristor emulator is the controllable threshold, where the state of the memristor can be changed by setting the control voltage, which makes the memristor circuit design more flexible. The operation frequency of the memristor emulator is about 250 kHz. The experimental results prove the feasibility and correctness of the threshold-controllable memristor emulator circuit.

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Reconfigurable halide perovskite nanocrystal memristors for neuromorphic computing

Cited by 109 publications

References 69 publications

On-device Synaptic Memory Consolidation using Fowler-Nordheim Quantum-tunneling

On-device Synaptic Memory Consolidation using Fowler-Nordheim Quantum-tunneling

Donor Engineering Tuning the Analog Switching Range and Operational Stability of Organic Synaptic Transistors for Neuromorphic Systems

Design of the Threshold-Controllable Memristor Emulator Based on NDR Characteristics

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