A biomimetic afferent nervous system based on the flexible artificial synapse

Biomimetic afferent nervous system (ANS) is urgently needed in the booming development of neuromorphic chips and artificial intelligent robots. It is necessary to make biomimetic ANS stably respond to the real irritation (heat or touch), not the conventionally used electric stimuli, in a manner of low-power-consumption, flexibility and miniaturization. Here, we present a chip-like flexible ANS device by fusing the ion conductive elastomer (ICE) with the MXene artificial synapse. It can not only successfully generate stable response to the joint flexion behaviors and weak pulse at radial artery, but also the plastic neural response can be simulated. Theoretical explanation for the proposed biomimetic ANS device is investigated by integrating the simulated geometry deformation, ion migration theory and trap assisted tunnel effect. Furthermore, the proposed device is applied to mimic an interesting operant conditioned reflex behavior by using a typical trial and error learning experiment. The transformations from short-term memory to long-term memory during two operant conditioning reflex stages (training and experiencing) are implemented. Conclusively, the sensory behaviors in biological ANS are simulated by the proposed device, which demonstrates its powerful ability of generating plastic neuroimpulse to real stimuli, thereby granting it a new role to realize the anthropomorphic sensation.

Automated summary

This study presents a chip-like flexible biomimetic afferent nervous system (ANS) device that combines ion conductive elastomer (ICE) with MXene artificial synapse. It successfully simulates the sensory behaviors of biological ANS and generates plastic neuroimpulse in response to real stimuli, allowing for the transformation from short-term memory to long-term memory.