Nature Communications (Nov 2023)

High-performance van der Waals antiferroelectric CuCrP2S6-based memristors

  • Yinchang Ma,
  • Yuan Yan,
  • Linqu Luo,
  • Sebastian Pazos,
  • Chenhui Zhang,
  • Xiang Lv,
  • Maolin Chen,
  • Chen Liu,
  • Yizhou Wang,
  • Aitian Chen,
  • Yan Li,
  • Dongxing Zheng,
  • Rongyu Lin,
  • Hanin Algaidi,
  • Minglei Sun,
  • Jefferson Zhe Liu,
  • Shaobo Tu,
  • Husam N. Alshareef,
  • Cheng Gong,
  • Mario Lanza,
  • Fei Xue,
  • Xixiang Zhang

DOI
https://doi.org/10.1038/s41467-023-43628-x
Journal volume & issue
Vol. 14, no. 1
pp. 1 – 11

Abstract

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Abstract Layered thio- and seleno-phosphate ferroelectrics, such as CuInP2S6, are promising building blocks for next-generation nonvolatile memory devices. However, because of the low Curie point, the CuInP2S6-based memory devices suffer from poor thermal stability (<42 °C). Here, exploiting the electric field-driven phase transition in the rarely studied antiferroelectric CuCrP2S6 crystals, we develop a nonvolatile memristor showing a sizable resistive-switching ratio of ~ 1000, high switching endurance up to 20,000 cycles, low cycle-to-cycle variation, and robust thermal stability up to 120 °C. The resistive switching is attributed to the ferroelectric polarization-modulated thermal emission accompanied by the Fowler–Nordheim tunneling across the interfaces. First-principles calculations reveal that the good device performances are associated with the exceptionally strong ferroelectric polarization in CuCrP2S6 crystal. Furthermore, the typical biological synaptic learning rules, such as long-term potentiation/depression and spike amplitude/spike time-dependent plasticity, are also demonstrated. The results highlight the great application potential of van der Waals antiferroelectrics in high-performance synaptic devices for neuromorphic computing.