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Protonic solid-state electrochemical synapse for physical neural networks

Author

Listed:
  • Xiahui Yao

    (Massachusetts Institute of Technology)

  • Konstantin Klyukin

    (Massachusetts Institute of Technology)

  • Wenjie Lu

    (Massachusetts Institute of Technology)

  • Murat Onen

    (Massachusetts Institute of Technology)

  • Seungchan Ryu

    (Massachusetts Institute of Technology)

  • Dongha Kim

    (Massachusetts Institute of Technology)

  • Nicolas Emond

    (Massachusetts Institute of Technology)

  • Iradwikanari Waluyo

    (Brookhaven National Laboratory)

  • Adrian Hunt

    (Brookhaven National Laboratory)

  • Jesús A. del Alamo

    (Massachusetts Institute of Technology)

  • Ju Li

    (Massachusetts Institute of Technology
    Massachusetts Institute of Technology)

  • Bilge Yildiz

    (Massachusetts Institute of Technology
    Massachusetts Institute of Technology)

Abstract

Physical neural networks made of analog resistive switching processors are promising platforms for analog computing. State-of-the-art resistive switches rely on either conductive filament formation or phase change. These processes suffer from poor reproducibility or high energy consumption, respectively. Herein, we demonstrate the behavior of an alternative synapse design that relies on a deterministic charge-controlled mechanism, modulated electrochemically in solid-state. The device operates by shuffling the smallest cation, the proton, in a three-terminal configuration. It has a channel of active material, WO3. A solid proton reservoir layer, PdHx, also serves as the gate terminal. A proton conducting solid electrolyte separates the channel and the reservoir. By protonation/deprotonation, we modulate the electronic conductivity of the channel over seven orders of magnitude, obtaining a continuum of resistance states. Proton intercalation increases the electronic conductivity of WO3 by increasing both the carrier density and mobility. This switching mechanism offers low energy dissipation, good reversibility, and high symmetry in programming.

Suggested Citation

  • Xiahui Yao & Konstantin Klyukin & Wenjie Lu & Murat Onen & Seungchan Ryu & Dongha Kim & Nicolas Emond & Iradwikanari Waluyo & Adrian Hunt & Jesús A. del Alamo & Ju Li & Bilge Yildiz, 2020. "Protonic solid-state electrochemical synapse for physical neural networks," Nature Communications, Nature, vol. 11(1), pages 1-10, December.
  • Handle: RePEc:nat:natcom:v:11:y:2020:i:1:d:10.1038_s41467-020-16866-6
    DOI: 10.1038/s41467-020-16866-6
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    Cited by:

    1. Fan Zhang & Yang Zhang & Linglong Li & Xing Mou & Huining Peng & Shengchun Shen & Meng Wang & Kunhong Xiao & Shuai-Hua Ji & Di Yi & Tianxiang Nan & Jianshi Tang & Pu Yu, 2023. "Nanoscale multistate resistive switching in WO3 through scanning probe induced proton evolution," Nature Communications, Nature, vol. 14(1), pages 1-8, December.
    2. Han Xu & Dashan Shang & Qing Luo & Junjie An & Yue Li & Shuyu Wu & Zhihong Yao & Woyu Zhang & Xiaoxin Xu & Chunmeng Dou & Hao Jiang & Liyang Pan & Xumeng Zhang & Ming Wang & Zhongrui Wang & Jianshi Ta, 2023. "A low-power vertical dual-gate neurotransistor with short-term memory for high energy-efficient neuromorphic computing," Nature Communications, Nature, vol. 14(1), pages 1-11, December.
    3. Sanghyeon Choi & Jaeho Shin & Gwanyeong Park & Jung Sun Eo & Jingon Jang & J. Joshua Yang & Gunuk Wang, 2024. "3D-integrated multilayered physical reservoir array for learning and forecasting time-series information," Nature Communications, Nature, vol. 15(1), pages 1-11, December.

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