Premium
Bacterial Cellulose Reinforced Polyaniline Electroconductive Hydrogel with Multiple Weak H‐Bonds as Flexible and Sensitive Strain Sensor
Author(s) -
Qin Hanglan,
Chen Yajun,
Huang Jieyu,
Wei Qufu
Publication year - 2021
Publication title -
macromolecular materials and engineering
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.913
H-Index - 96
eISSN - 1439-2054
pISSN - 1438-7492
DOI - 10.1002/mame.202100159
Subject(s) - polyaniline , materials science , self healing hydrogels , biocompatibility , viscoelasticity , bacterial cellulose , electrical conductor , conductive polymer , cellulose , piezoresistive effect , composite material , polymer , chemical engineering , polymer chemistry , engineering , metallurgy , polymerization
Hydrogel, as a promising soft material, possesses many functional advantages such as stretchability, viscoelasticity, and biocompatibility. An advanced electronic platform for strain sensor is constructed by modifying hydrogels with various doping techniques. Herein, a novel flexible conductive hydrogel is synthesized by combination of bacterial cellulose/sodium alginate/polyacrylamide with the polyaniline (BSP‐PANI) through multiple intermolecular interactions. In the obtained BSP‐PANI hydrogel system, the incorporated BC serves the function of mechanically toughening and the formation of polyaniline conducting network endows the hydrogels electrical conductivity. The assembled hydrogel strain sensor can detect electrical response under different applied strains (1–200%) and monitor human motion in real time. Therefore, it is believed that the BSP‐PANI hydrogel prepared by the feasible synergetic strategy proposed in this work has greatly diversified application in smart epidermal sensors and artificial intelligence devices.