Research (Jan 2019)

A Photoelectric-Stimulated MoS2 Transistor for Neuromorphic Engineering

  • Shuiyuan Wang,
  • Xiang Hou,
  • Lan Liu,
  • Jingyu Li,
  • Yuwei Shan,
  • Shiwei Wu,
  • David Wei Zhang,
  • Peng Zhou

DOI
https://doi.org/10.34133/2019/1618798
Journal volume & issue
Vol. 2019

Abstract

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The von Neumann bottleneck has spawned the rapid expansion of neuromorphic engineering and brain-like networks. Synapses serve as bridges for information transmission and connection in the biological nervous system. The direct implementation of neural networks may depend on novel materials and devices that mimic natural neuronal and synaptic behavior. By exploiting the interfacial effects between MoS2 and AlOx, we demonstrate that an h-BN-encapsulated MoS2 artificial synapse transistor can mimic the basic synaptic behaviors, including EPSC, PPF, LTP, and LTD. Efficient optoelectronic spikes enable simulation of synaptic gain, frequency, and weight plasticity. The Pavlov classical conditioning experiment was successfully simulated by electrical tuning, showing associated learning behavior. In addition, h-BN encapsulation effectively improves the environmental time stability of our devices. Our h-BN-encapsulated MoS2 artificial synapse provides a new paradigm for hardware implementation of neuromorphic engineering.