Fabrication of a Highly Sensitive Stretchable Strain Sensor Utilizing a Microfibrous Membrane and a Cracking Structure on Conducting Polymer

Recently, the detection of human motion has attracted considerable attention for the development of smart healthcare systems. Flexible or stretchable strain sensors are required to measure deformations on arbitrarily shaped human skin areas caused by human motion, and numerous studies have explored...

Full description

Saved in:
Bibliographic Details
Published inMacromolecular materials and engineering Vol. 303; no. 1
Main Authors Jeon, Hyungkook, Hong, Seong Kyung, Cho, Seong J., Lim, Geunbae
Format Journal Article
LanguageEnglish
Published Weinheim John Wiley & Sons, Inc 01.01.2018
Subjects
alignment control of fibrous membrane
Conducting polymers
cracking structure
Deformation mechanisms
electrospinning
Human motion
Microfibers
Motion perception
Polymers
Resistance
Sensitivity
Sensors
Skin
Strain
stretchable strain sensor
Online AccessGet full text

Cover

More Information
Summary:Recently, the detection of human motion has attracted considerable attention for the development of smart healthcare systems. Flexible or stretchable strain sensors are required to measure deformations on arbitrarily shaped human skin areas caused by human motion, and numerous studies have explored the development of such sensors. Here, a highly sensitive stretchable strain sensor is introduced, which consists of elastic fibrous membrane coated with conducting polymer. The membrane can be utilized to detect applied strain by measuring the conductance change caused by the change in the nanocracking structure on the coated conducting polymer layer. Furthermore, by collecting aligned microfibers as the fibrous membrane during electrospinning process, the sensor exhibits higher sensitivity (more than 40‐fold higher than the nonaligned version). Although limitations still remain in the repeatability and the applicability of the sensor, the developed sensor will demonstrate great potential for measuring applied strain and stress over a wide sensing range with high sensitivity is expected. A highly sensitive stretchable strain sensor is introduced, which consists of elastic fibrous membrane coated with conducting polymer. The sensor can detect applied strain by measuring the conductance change caused by the change in the nanocracking structure on the coated conducting polymer. Furthermore, by aligning microfibers, the sensitivity of the sensor is dramatically enhanced (more than 40‐fold higher).
ISSN:1438-7492
1439-2054
DOI:10.1002/mame.201700389