Large quantities of fish are consumed in India on a daily basis, which generates a huge amount of fish “biowaste” materials. In an attempt to do something positive with this biowaste, a team of researchers at Jadavpur University in Koltata, India explored recycling the fish byproducts into an energy harvester for self-powered electronics. Fish scales contain collagen fibers that possess a piezoelectric property, ie electric charge is generated in response to applying a mechanical stress. They were able to harness it to fabricate a bio-piezoelectric nanogenerator.
To do this, they first “collected biowaste in the form of hard, raw fish scales from a fish processing market, and then used a demineralization process to make them transparent and flexible,” explained Assistant Prof. Dipankar Mandal, Jadavpur University. The collagens within the processed fish scales serve as an active piezoelectric element. “We were able to make a bio-piezoelectric nanogenerator—a.k.a. energy harvester—with electrodes on both sides, and then laminated it,” Mandal said.
While it’s well known that a single collagen nanofiber exhibits piezoelectricity, until now no one had attempted to focus on hierarchically organizing the collagen nanofibrils within the natural fish scales. “And we discovered that the piezoelectricity of the fish scale collagen is quite large (~5 pC/N), which we were able to confirm via direct measurement.” Beyond that, the polarization-electric field hysteresis loop and resulting strain-electric field hysteresis loop—proof of a converse piezoelectric effect—caused by the “nonlinear” electrostriction effect backed up their findings.
The team’s work is the first known demonstration of the direct piezoelectric effect of fish scales from electricity generated by a bio-piezoelectric nanogenerator under mechanical stimuli—without the need for any post-electrical poling treatments.
“We’re well aware of the disadvantages of the post-processing treatments of piezoelectric materials,” Mandal noted.
To explore the fish scale collagen’s self-alignment phenomena, the researchers used near-edge X-ray absorption fine-structure spectroscopy. Experimental and theoretical tests helped them clarify the energy scavenging performance of the bio-piezoelectric nanogenerator. It’s capable of scavenging several types of ambient mechanical energies—including body movements, machine and sound vibrations, and wind flow. Even repeatedly touching the bio-piezoelectric nanogenerator with a finger can turn on more than 50 blue LEDs. “We expect our work to greatly impact the field of self-powered flexible electronics,” Mandal said.
Apps: transparent electronics, biocompatible and biodegradable electronics, edible electronics, self-powered implantable medical devices, surgeries, e-healthcare monitoring, as well as in vitro and in vivo diagnostics, apart from its myriad uses for portable electronics. “In the future, our goal is to implant a bio-piezoelectric nanogenerator into a heart for pacemaker devices, where it will continuously generate power from heartbeats for the device’s operation,” Mandal said. “Then it will degrade when no longer needed. Since heart tissue is also composed of collagen, our bio-piezoelectric nanogenerator is expected to be very compatible with the heart.”
The group’s bio-piezoelectric nanogenerator may also help with targeted drug delivery, which is currently generating interest as a way of recovering in vivo cancer cells and also to stimulate different types of damaged tissues. “So we expect our work to have enormous importance for next-generation implantable medical devices,” he added. “Our end goal is to design and engineer sophisticated ingestible electronics composed of nontoxic materials that are useful for a wide range of diagnostic and therapeutic applications,” said Mandal.
http://www.eurekalert.org/pub_releases/2016-09/aiop-fc090216.php
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