Weighted Echo State Graph Neural Networks Based on Robust and Epitaxial Film Memristors
Authors
Guo, ZhenqiangDuan, Guojun
Zhang, Yinxing
Sun, Yong
Zhang, Weifeng
Li, Xiaohan
Shi, Haowan
Li, Pengfei
Zhao, Zhen
Xu, Jikang
Yang, Biao
Faraj, Yousef
Yan, Xiaobing
Affiliation
Hebei University; University of ChesterPublication Date
2025-01-04
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Hardware system customized toward the demands of graph neural network learning would promote efficiency and strong temporal processing for graph‐structured data. However, most amorphous/polycrystalline oxides‐based memristors commonly have unstable conductance regulation due to random growth of conductive filaments. And graph neural networks based on robust and epitaxial film memristors can especially improve energy efficiency due to their high endurance and ultra‐low power consumption. Here, robust and epitaxial Gd: HfO2‐based film memristors are reported and construct a weighted echo state graph neural network (WESGNN). Benefiting from the optimized epitaxial films, the high switching speed (20 ns), low energy consumption (2.07 fJ), multi‐value storage (4 bits), and high endurance (109) outperform most memristors. Notably, thanks to the appropriately dispersed conductance distribution (standard deviation = 7.68 nS), the WESGNN finely regulates the relative weights of input nodes and recursive matrix to realize state‐of‐the‐art performance using the MUTAG and COLLAB datasets for graph classification tasks. Overall, robust and epitaxial film memristors offer nanoscale scalability, high reliability, and low energy consumption, making them energy‐efficient hardware solutions for graph learning applications.Citation
Guo, Z., Duan, G., Zhang, Y., Sun, Y., Zhang, W., Li, X., Shi, H., Li, P., Zhao, Z., Xu, J., Yang, B., Faraj, Y., & Yan, X. (2025). Weighted echo state graph neural networks based on robust and epitaxial film memristors. Advanced Science, vol(issue), article-number 2411925. https://doi.org/10.1002/advs.202411925Publisher
WileyJournal
Advanced ScienceAdditional Links
https://onlinelibrary.wiley.com/doi/10.1002/advs.202411925Type
ArticleDescription
© 2025 The Author(s). Advanced Science published by Wiley-VCH GmbHEISSN
2198-3844Sponsors
National key R&D plan “nano frontier” key special project (grant no. 2021YFA1200502 and 2024YFA1208400), Disruptive Technology Innovation Project of the National Key R&D Program (grant no. DT01202402075), Interdisciplinary Research Program of Natural Science (grant no. DXK202101), Cultivation projects of national major R & D project (grant no. 92164109), National Natural Science Foundation of China (grant nos. 61674050 and 61874158), Special project of strategic leading science and technology of Chinese Academy of Sciences (grant no. XDB44000000-7), Hebei Basic Research Special Key Project (grant no. F2021201045), the Project of Distinguished Young of Hebei Province (grant no. A2018201231), the Support Program for the Top Young Talents of Hebei Province (grant no. 70280011807), the Hundred Persons Plan of Hebei Province (grant nos. E2018050004 and E2018050003), the Supporting Plan for 100 Excellent Innovative Talents in Colleges and Universities of Hebei Province (grant no. SLRC2019018), outstanding young scientific research and innovation team of Hebei University (grant no. 605020521001), Special support funds for national high level talents (grant no. 041500120001), High-level Talent Research Startup Project of Hebei University (grant no. 521000981426), Funded by Science and Technology Project of Hebei Education Department (grant nos. QN2020178, QN2021026), Baoding Science and Technology Plan Project (2172P011, 2272P014), Postgraduate's Innovation Fund Project of Hebei Province (CXZZBS2024004).ae974a485f413a2113503eed53cd6c53
10.1002/advs.202411925
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