Laser Writing of Janus Graphene/Kevlar Textile for Intelligent Protective Clothing

Overview

Journal ACS Nano

Publisher American Chemical Society

Specialty Biotechnology

Date 2020 Feb 22

PMID 32083839

Citations 27

Authors

Huimin Wang

Haomin Wang

Yiliang Wang

Xinyi Su

Chunya Wang

Mingchao Zhang

Muqiang Jian

Kailun Xia

Xiaoping Liang

Haojie Lu

Shuo Li

Yingying Zhang

Affiliations

Soon will be listed here.

Abstract

Protective clothing plays a vital role in safety and security. Traditional protective clothing can protect the human body from physical injury. It is highly desirable to integrate modern wearable electronics into a traditional protection suit to endow it with versatile smart functions. However, it is still challenging to integrate electronics into clothing through a practical approach while keeping the intrinsic flexibility and breathability of textiles. In this work, we realized the direct writing of laser-induced graphene (LIG) on a Kevlar textile in air and demonstrated the applications of the as-prepared Janus graphene/Kevlar textile in intelligent protective clothing. The C═O and N-C bonds in Kevlar were broken, and the remaining carbon atoms were reorganized into graphene, which can be ascribed to a photothermal effect induced by the laser irradiation. Proof-of-concept devices based on the prepared graphene/Kevlar textile, including flexible Zn-air batteries, electrocardiogram electrodes, and NO sensors, were demonstrated. Further, we fabricated self-powered and intelligent protective clothing based on the graphene/Kevlar textile. The laser-induced direct writing of graphene from commercial textiles in air conditions provides a versatile and rapid route for the fabrication of textile electronics.

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