0531 GMT October 20, 2019
That's the idea behind a collaborative research project led by University at Buffalo (UB) and Institute of Semiconductors (IoP) at Chinese Academy of Science (CAS), sciencedaily.com wrote.
The tab — a triboelectric nanogenerator — is described in a study published in the journal Nano Energy.
Lead author Qiaoqiang Gan, PhD, associate professor of electrical engineering in UB's School of Engineering and Applied Sciences, said, "No one likes being tethered to a power outlet or lugging around a portable charger.
“The human body is an abundant source of energy. We thought: Why not harness it to produce our own power?”
Triboelectric charging occurs when certain materials become electrically charged after coming into contact with a different material. Most everyday static electricity is triboelectric.
Researchers have proposed numerous nanogenerators that utilize the triboelectric effect; however, most are difficult to manufacture (requiring complex lithography) or are not cost effective.
The tab that the UB and CAS team are developing addresses both of those concerns.
It consists of two thin layers of gold, with polydimethylsiloxane (also called PDMS, a silicon-based polymer used in contact lenses, Silly Putty and other products) sandwiched in between.
Key to the device is that one layer of gold is stretched, causing it to crumple upon release and create what looks like a miniature mountain range.
When that force is reapplied, for example from a finger bending, the motion leads to friction between the gold layers and PDMS.
Another lead author, Yun Xu, PhD, professor of IoP at CAS, said, "This causes electrons to flow back and forth between the gold layers. The more friction, the greater the amount of power is produced.”
The study describes a small tab (1.5 centimeters long, by one centimeter wide).
It delivered a maximum voltage of 124 volts, a maximum current of 10 microamps and a maximum power density of 0.22 mill watts per square centimeter.
That's not enough to quickly charge a smartphone; however it lit 48 red LED lights simultaneously.
Coauthors of the study include Huamin Chen at IoP and CAS; and Nan Zhang, a PhD student at UB.
Because the tab is easily fabricated, Zhang is leading a team of UB undergraduates which is tasked with improving the tab's performance.
The team plans to use larger pieces of gold, which when stretched and folded together are expected to deliver even more electricity.
Researchers are also working on developing a portable battery to store energy produced by the tab.
They envision the system serving as a power source for various wearable and self-powered electronic devices.