posted on 2018-12-20, 00:00authored byTran Quang Trung, Thi My Linh Dang, Subramaniyan Ramasundaram, Phan Tan Toi, Sang Yoon Park, Nae-Eung Lee
To realize the potential
applications of stretchable sensors in
the field of wearable health monitoring, it is essential to develop
a stable sensing device with robust electrical and mechanical properties
in the present of varying external conditions. Herein, we demonstrate
a stretchable temperature sensor with the elimination of strain-induced
interference via geometric engineering of the free-standing stretchable
fibers (FSSFs) of reduced graphene oxide/polyurethane composite. The
FSSFs were formed in serpentine structures and enabled the implementation
of a strain-insensitive stretchable temperature sensor. On the basis
of the controlled reduction time of graphene oxide, we can modulate
the response and thermal index of the device. These results are attributed
to the variation in the density of oxygen-containing functional groups
in the FSSFs, which affect the hopping charge transport and thermal
generation of excess carriers. The FSSF temperature sensor yields
increased responsivity (0.8%/°C), stretchability (90%), sensing
resolution (0.1 °C), and stability in response to applied stretching
(±0.37 °C for strains ranging from 0 to 50%). When the sensor
is sewn onto a stretchable bandage and attached to the human body,
it can detect the temperature changes of the human skin during different
body motions in a continuous and stable manner.