posted on 2022-10-06, 15:38authored byWedyan Babatain, Ulrich Buttner, Nazek El-Atab, Muhammad Mustafa Hussain
Motion sensors are an essential component of many electronic
systems.
However, the development of inertial motion sensors based on fatigue-free
soft proof mass has not been explored extensively in the field of
soft electronics. Nontoxic gallium-based liquid metals are an emerging
class of material that exhibit attractive electromechanical properties,
making them excellent proof mass materials for inertial sensors. Here,
we propose and demonstrate a fully soft laser-induced graphene (LIG)
and liquid metal-based inertial sensor integrated with temperature,
humidity, and breathing sensors. The inertial sensor design confines
a graphene-coated liquid metal droplet inside a fluidic channel, rolling
over LIG resistive electrode. The proposed sensor architecture and
material realize a highly mobile proof mass and a vibrational space
for its oscillation. The inertial sensor exhibits a high sensitivity
of 6.52% m–1 s2 and excellent repeatability
(over 12 500 cycles). The platform is fabricated using a scalable,
rapid laser writing technique and integrated with a programmable system
on a chip (PSoC) to function as a stand-alone system for real-time
wireless monitoring of movement patterns and the control of a robotic
arm. The developed printed inertial platform is an excellent candidate
for the next-generation of wearables motion tracking platforms and
soft human–machine interfaces.