iScience (Nov 2020)

Two-Dimensional Near-Atom-Thickness Materials for Emerging Neuromorphic Devices and Applications

  • Tae-Jun Ko,
  • Hao Li,
  • Sohrab Alex Mofid,
  • Changhyeon Yoo,
  • Emmanuel Okogbue,
  • Sang Sub Han,
  • Mashiyat Sumaiya Shawkat,
  • Adithi Krishnaprasad,
  • Molla Manjurul Islam,
  • Durjoy Dev,
  • Yongjun Shin,
  • Kyu Hwan Oh,
  • Gwan-Hyoung Lee,
  • Tania Roy,
  • Yeonwoong Jung

Journal volume & issue
Vol. 23, no. 11
p. 101676

Abstract

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Summary: Two-dimensional (2D) layered materials and their heterostructures have recently been recognized as promising building blocks for futuristic brain-like neuromorphic computing devices. They exhibit unique properties such as near-atomic thickness, dangling-bond-free surfaces, high mechanical robustness, and electrical/optical tunability. Such attributes unattainable with traditional electronic materials are particularly promising for high-performance artificial neurons and synapses, enabling energy-efficient operation, high integration density, and excellent scalability. In this review, diverse 2D materials explored for neuromorphic applications, including graphene, transition metal dichalcogenides, hexagonal boron nitride, and black phosphorous, are comprehensively overviewed. Their promise for neuromorphic applications are fully discussed in terms of material property suitability and device operation principles. Furthermore, up-to-date demonstrations of neuromorphic devices based on 2D materials or their heterostructures are presented. Lastly, the challenges associated with the successful implementation of 2D materials into large-scale devices and their material quality control will be outlined along with the future prospect of these emergent materials.

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