posted on 2022-08-10, 23:40authored byLexin Liu, Yimeng Ni, Jiajun Mao, Shuhui Li, Kim Hoong Ng, Zhong Chen, Jianying Huang, Weilong Cai, Yuekun Lai
To date, multifunctional sensors have aroused widespread
concerns
owing to their vital roles in the healthcare area. However, there
are still significant challenges in the fabrication of functionalized
integrated devices. In this work, hydrophobic–hydrophilic patterns
are constructed on polyester-spandex-blended knitted fabric surface
by the chemical click method, enabling accurate deposition of functionalized
materials for sensitive and stable motion and humidity sensing. Representatively,
a conductive silver nanowire (Ag NW) network was deliberately deposited
on only the designated hydrophilic fabric surface to realize accurate,
repeatable, and stable motion sensing. Such a Ag NWs sensor recorded
a low electrical resistance (below 60 Ω), stable resistance
cycling response (over 2000 cycles), and fast response time to humidity
(0.46 s) during the sensing evaluation. In addition to experimental
sensing, real human motions, such as mouth-opening and joint-flexing
(wrist and neck), could also be detected using the same sensor. Similar
promising outputs were also obtained over the humidity sensor fabricated
over the same chemical click method, except the sensing material was
replaced with polydopamine-modified carboxylated carbon nanotubes.
The resultant sensor exhibits excellent sensitivity to not only experimentally
adjusted environment humidity but also to the moisture content of
breath and skin during daily activities. On top of all these, both
sensors were fabricated over highly flexible fabric that offers high
wearability, promising great application potential in the field of
healthcare monitoring.