Stretchable and Self-Powered Mechanoluminescent Triboelectric Nanogenerator Fibers Toward Wearable Amphibious Electro-Optical Sensor Textiles

Overview

Journal Adv Sci (Weinh)

Specialty Biomedical Engineering

Date 2024 Jul 6

PMID 38970168

Authors

Jiajun Wu

Xuhui Zhou

Jie Luo

Jianxian Zhou

Zecheng Lu

Zhiqing Bai

Yuan Fan

Xuedan Chen

Bin Zheng

Zhanyong Wang

Lei Wei

Qichong Zhang

Affiliations

Soon will be listed here.

Abstract

Flexible electro-optical dual-mode sensor fibers with capability of the perceiving and converting mechanical stimuli into digital-visual signals show good prospects in smart human-machine interaction interfaces. However, heavy mass, low stretchability, and lack of non-contact sensing function seriously impede their practical application in wearable electronics. To address these challenges, a stretchable and self-powered mechanoluminescent triboelectric nanogenerator fiber (MLTENGF) based on lightweight carbon nanotube fiber is successfully constructed. Taking advantage of their mechanoluminescent-triboelectric synergistic effect, the well-designed MLTENGF delivers an excellent enhancement electrical signal of 200% and an evident optical signal whether on land or underwater. More encouragingly, the MLTENGF device possesses outstanding stability with almost unchanged sensitivity after stretching for 200%. Furthermore, an extraordinary non-contact sensing capability with a detection distance of up to 35 cm is achieved for the MLTENGF. As application demonstrations, MLTENGFs can be used for home security monitoring, intelligent zither, traffic vehicle collision avoidance, and underwater communication. Thus, this work accelerates the development of wearable electro-optical textile electronics for smart human-machine interaction interfaces.

Citing Articles

Stretchable and Self-Powered Mechanoluminescent Triboelectric Nanogenerator Fibers toward Wearable Amphibious Electro-Optical Sensor Textiles.

Wu J, Zhou X, Luo J, Zhou J, Lu Z, Bai Z Adv Sci (Weinh). 2024; 11(34):e2401109.

PMID: 38970168 PMC: 11425994. DOI: 10.1002/advs.202401109.

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