# Ultrasensitive hybrid optical skin

**Authors:** Lei Zhang, Jing Pan, Zhang Zhang, Hao Wu, Ni Yao, Dawei Cai, Yingxin, Xu, Jin Zhang, Guofei Sun, Liqiang Wang, Weidong Geng, Wenguang Jin, Wei, Fang, Dawei Di, Limin Tong

arXiv: 1812.03808 · 2018-12-11

## TL;DR

This paper introduces a highly sensitive optical skin (O-skin) that uses embedded glass micro/nanofibers to achieve ultrahigh sensitivity, fast response, and EMI-free detection, surpassing traditional electronic skins in various sensing applications.

## Contribution

The authors develop a novel optical skin using embedded glass micro/nanofibers, enabling ultrahigh sensitivity and fast response in wearable sensors, overcoming limitations of electronic skin.

## Key findings

- Achieved pressure sensitivity of 1870/kPa
- Detected vibrations, pulse, and voice EMI-free
- Demonstrated optical data glove and tactile sensor

## Abstract

Electronic skin, a class of wearable electronic sensors that mimic the functionalities of human skin, has made remarkable success in applications including health monitoring, human-machine interaction and electronic-biological interfaces. While electronic skin continues to achieve higher sensitivity and faster response, its ultimate performance is fundamentally limited by the nature of low-frequency AC currents in electronic circuitries. Here we demonstrate highly sensitive optical skin (O-skin) in which the primary sensory elements are optically driven. The simple construction of the sensors is achieved by embedding glass micro/nanofibers (MNFs) in thin layers of polydimethylsiloxane (PDMS). Enabled by the highly sensitive power-leakage response of the guided modes from the MNF upon external stimuli, our optical sensors show ultrahigh sensitivity (1870/kPa), low detection limit (7 mPa) and fast response (10 microseconds) for pressure sensing, significantly exceeding the performance metrics of state-of-the-art electronic skins. Electromagnetic interference (EMI)-free detection of high-frequency vibrations, wrist pulse and human voice are realized. Moreover, a five-sensor optical data glove and a 2x2-MNF tactile sensor are demonstrated. Our results pave the way toward wearable optical devices ranging from ultrasensitive flexible sensors to optical skins.

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Source: https://tomesphere.com/paper/1812.03808