Issue 9, 2024

Ovonic threshold switching-based artificial afferent neurons for thermal in-sensor computing

Abstract

Artificial afferent neurons in the sensory nervous system inspired by biology have enormous potential for efficiently perceiving and processing environmental information. However, the previously reported artificial afferent neurons suffer from two prominent challenges: considerable power consumption and limited scalability efficiency. Herein, addressing these challenges, a bioinspired artificial thermal afferent neuron based on a N-doped SiTe ovonic threshold switching (OTS) device is presented for the first time. The engineered OTS device shows remarkable uniformity and robust endurance, ensuring the reliability and efficacy of the artificial afferent neurons. A substantially decreased leakage current of the SiTe OTS device by nitrogen doping results in ultra-low power consumption less than 0.3 nJ per spike for artificial afferent neurons. The inherent temperature response exhibited by N-doped SiTe OTS materials allows us to construct a highly compact artificial thermal afferent neuron over a wide temperature range. An edge detection task is performed to further verify its thermal perceptual computing function. Our work provides an insight into OTS-based artificial afferent neurons for electronic skin and sensory neurorobotics.

Graphical abstract: Ovonic threshold switching-based artificial afferent neurons for thermal in-sensor computing

Supplementary files

Article information

Article type
Communication
Submitted
16 1 2024
Accepted
19 3 2024
First published
21 3 2024

Mater. Horiz., 2024,11, 2106-2114

Ovonic threshold switching-based artificial afferent neurons for thermal in-sensor computing

K. Li, J. Yao, P. Zhao, Y. Luo, X. Ge, R. Yang, X. Cheng and X. Miao, Mater. Horiz., 2024, 11, 2106 DOI: 10.1039/D4MH00053F

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