Nature Communications (Sep 2023)

Light-enhanced molecular polarity enabling multispectral color-cognitive memristor for neuromorphic visual system

  • Jongmin Lee,
  • Bum Ho Jeong,
  • Eswaran Kamaraj,
  • Dohyung Kim,
  • Hakjun Kim,
  • Sanghyuk Park,
  • Hui Joon Park

DOI
https://doi.org/10.1038/s41467-023-41419-y
Journal volume & issue
Vol. 14, no. 1
pp. 1 – 19

Abstract

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Abstract An optoelectronic synapse having a multispectral color-discriminating ability is an essential prerequisite to emulate the human retina for realizing a neuromorphic visual system. Several studies based on the three-terminal transistor architecture have shown its feasibility; however, its implementation with a two-terminal memristor architecture, advantageous to achieving high integration density as a simple crossbar array for an ultra-high-resolution vision chip, remains a challenge. Furthermore, regardless of the architecture, it requires specific material combinations to exhibit the photo-synaptic functionalities, and thus its integration into various systems is limited. Here, we suggest an approach that can universally introduce a color-discriminating synaptic functionality into a two-terminal memristor irrespective of the kinds of switching medium. This is possible by simply introducing the molecular interlayer with long-lasting photo-enhanced dipoles that can adjust the resistance of the memristor at the light-irradiation. We also propose the molecular design principle that can afford this feature. The optoelectronic synapse array having a color-discriminating functionality is confirmed to improve the inference accuracy of the convolutional neural network for the colorful image recognition tasks through a visual pre-processing. Additionally, the wavelength-dependent optoelectronic synapse can also be leveraged in the design of a light-programmable reservoir computing system.