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High-speed and energy-efficient non-volatile silicon photonic memory based on heterogeneously integrated memresonator

Author

Listed:
  • Bassem Tossoun

    (Hewlett Packard Enterprise)

  • Di Liang

    (Hewlett Packard Enterprise
    University of Michigan, Department of Electrical and Computer Engineering)

  • Stanley Cheung

    (Hewlett Packard Enterprise)

  • Zhuoran Fang

    (Hewlett Packard Enterprise)

  • Xia Sheng

    (Hewlett Packard Enterprise)

  • John Paul Strachan

    (Hewlett Packard Enterprise
    PGI-14, Forschungszentrum Jülich GmbH)

  • Raymond G. Beausoleil

    (Hewlett Packard Enterprise)

Abstract

Recently, interest in programmable photonics integrated circuits has grown as a potential hardware framework for deep neural networks, quantum computing, and field programmable arrays (FPGAs). However, these circuits are constrained by the limited tuning speed and large power consumption of the phase shifters used. In this paper, we introduce the memresonator, a metal-oxide memristor heterogeneously integrated with a microring resonator, as a non-volatile silicon photonic phase shifter. These devices are capable of retention times of 12 hours, switching voltages lower than 5 V, and an endurance of 1000 switching cycles. Also, these memresonators have been switched using 300 ps long voltage pulses with a record low switching energy of 0.15 pJ. Furthermore, these memresonators are fabricated on a heterogeneous III-V-on-Si platform capable of integrating a rich family of active and passive optoelectronic devices directly on-chip to enable in-memory photonic computing and further advance the scalability of integrated photonic processors.

Suggested Citation

  • Bassem Tossoun & Di Liang & Stanley Cheung & Zhuoran Fang & Xia Sheng & John Paul Strachan & Raymond G. Beausoleil, 2024. "High-speed and energy-efficient non-volatile silicon photonic memory based on heterogeneously integrated memresonator," Nature Communications, Nature, vol. 15(1), pages 1-8, December.
    • Handle: RePEc:nat:natcom:v:15:y:2024:i:1:d:10.1038_s41467-024-44773-7
    DOI: 10.1038/s41467-024-44773-7
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    References listed on IDEAS

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    1. Farshid Ashtiani & Alexander J. Geers & Firooz Aflatouni, 2022. "An on-chip photonic deep neural network for image classification," Nature, Nature, vol. 606(7914), pages 501-506, June.
    2. J. Feldmann & N. Youngblood & C. D. Wright & H. Bhaskaran & W. H. P. Pernice, 2019. "All-optical spiking neurosynaptic networks with self-learning capabilities," Nature, Nature, vol. 569(7755), pages 208-214, May.
    3. Can Li & Lili Han & Hao Jiang & Moon-Hyung Jang & Peng Lin & Qing Wu & Mark Barnell & J. Joshua Yang & Huolin L. Xin & Qiangfei Xia, 2017. "Three-dimensional crossbar arrays of self-rectifying Si/SiO2/Si memristors," Nature Communications, Nature, vol. 8(1), pages 1-9, August.
    4. Dmitri B. Strukov & Gregory S. Snider & Duncan R. Stewart & R. Stanley Williams, 2008. "The missing memristor found," Nature, Nature, vol. 453(7191), pages 80-83, May.
    5. Ying Zhang & Ge-Qi Mao & Xiaolong Zhao & Yu Li & Meiyun Zhang & Zuheng Wu & Wei Wu & Huajun Sun & Yizhong Guo & Lihua Wang & Xumeng Zhang & Qi Liu & Hangbing Lv & Kan-Hao Xue & Guangwei Xu & Xiangshui, 2021. "Evolution of the conductive filament system in HfO2-based memristors observed by direct atomic-scale imaging," Nature Communications, Nature, vol. 12(1), pages 1-10, December.
    6. Wen Sun & Bin Gao & Miaofang Chi & Qiangfei Xia & J. Joshua Yang & He Qian & Huaqiang Wu, 2019. "Understanding memristive switching via in situ characterization and device modeling," Nature Communications, Nature, vol. 10(1), pages 1-13, December.
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