3D Synergistical MXene/Reduced Graphene Oxide Aerogel for a Piezoresistive Sensor

Overview

Journal ACS Nano

Publisher American Chemical Society

Specialty Biotechnology

Date 2018 Apr 3

PMID 29608277

Citations 60

Authors

Yanan Ma

Yang Yue

Hang Zhang

Feng Cheng

Wanqiu Zhao

Jiangyu Rao

Shijun Luo

Jie Wang

Xueliang Jiang

Zhitian Liu

Nishuang Liu

Yihua Gao

Affiliations

Soon will be listed here.

Abstract

A piezoresistive sensor based on ultralight and superelastic aerogel is reported to fabricate MXene/reduced graphene oxide (MX/rGO) hybrid 3D structures and utilize their pressure-sensitive characteristics. The MX/rGO aerogel not only combines the rGO's large specific surface area and the MXene's (TiC T ) high conductivity but also exhibits rich porous structure, which leads to performance better than that of single-component rGO or MXene in terms of the pressure sensor. The large nanosheets of rGO can prevent the poor oxidization of MXene by wrapping MXene inside the aerogel. More importantly, the piezoresistive sensor based on the MX/rGO aerogel shows extremely high sensitivity (22.56 kPa), fast response time (<200 ms), and good stability over 10 000 cycles. The piezoresistive sensor based on the MX/rGO hybrid 3D aerogel can easily capture the signal below 10 Pa, thus clearly testing the pulse of an adult at random. Based on its superior performance, it also demonstrates potential applications in measuring pressure distribution, distinguishing subtle strain, and monitoring healthy activity.

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