Nature Communications (Apr 2024)

Memory-electroluminescence for multiple action-potentials combination in bio-inspired afferent nerves

  • Kun Wang,
  • Yitao Liao,
  • Wenhao Li,
  • Junlong Li,
  • Hao Su,
  • Rong Chen,
  • Jae Hyeon Park,
  • Yongai Zhang,
  • Xiongtu Zhou,
  • Chaoxing Wu,
  • Zhiqiang Liu,
  • Tailiang Guo,
  • Tae Whan Kim

DOI
https://doi.org/10.1038/s41467-024-47641-6
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 11

Abstract

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Abstract The development of optoelectronics mimicking the functions of the biological nervous system is important to artificial intelligence. This work demonstrates an optoelectronic, artificial, afferent-nerve strategy based on memory-electroluminescence spikes, which can realize multiple action-potentials combination through a single optical channel. The memory-electroluminescence spikes have diverse morphologies due to their history-dependent characteristics and can be used to encode distributed sensor signals. As the key to successful functioning of the optoelectronic, artificial afferent nerve, a driving mode for light-emitting diodes, namely, the non-carrier injection mode, is proposed, allowing it to drive nanoscale light-emitting diodes to generate a memory-electroluminescence spikes that has multiple sub-peaks. Moreover, multiplexing of the spikes can be obtained by using optical signals with different wavelengths, allowing for a large signal bandwidth, and the multiple action-potentials transmission process in afferent nerves can be demonstrated. Finally, sensor-position recognition with the bio-inspired afferent nerve is developed and shown to have a high recognition accuracy of 98.88%. This work demonstrates a strategy for mimicking biological afferent nerves and offers insights into the construction of artificial perception systems.