PROF. JAYAN THOMAS DEVELOPED STORE ELECTRICITY IN A SINGLE LIGHT WEIGHT
COPPER WIRE
Imagine
being able to carry all the juice you needed to power your MP3 player,
smartphone and electric car in the fabric of your jacket?Sounds like science
fiction, but it may become a reality thanks to breakthrough technology
developed at a University of Central Florida research lab.So far
electrical cables are used only to transmit electricity. However,
nanotechnology scientist and professor Jayan Thomas and his Ph.D. student Zenan
Yu have developed a way to both transmit and store electricity in a single
lightweight copper wire.Their work is the focus of the cover story of the June
30 issue of the material science journal Advanced Materials and science
magazine Nature has
published a detailed discussion about this technology in the current issue.
“It’s
an interesting idea,” Thomas said. “When we did it and started talking about
it, everyone we talked to said, ‘Hmm, never thought of that. It’s unique.’”Copper
wire is the starting point but eventually, Thomas said, as the technology
improves, special fibers could also be developed with nanostructures to conduct
and store energy.
More
immediate applications could be seen in the design and development of
electrical vehicles, space-launch vehicles and portable electronic devices. By
being able to store and conduct energy on the same wire, heavy, space-consuming
batteries could become a thing of the past. It is possible to further
miniaturize the electronic devices or the space that has been previously used
for batteries could be used for other purposes. In the case of launch vehicles,
that could potentially lighten the load, making launches less costly, Thomas
said.
Thomas
and his team began with a single copper wire. Then he placed a sheath over the
wire made up of nanowhiskers the team grew on the outer surface of the copper
wire. These whiskers were then treated with a special alloy, which created an
electrode. Two electrodes are needed for the powerful energy storage. So they
had to figure out a way to create a second electrode.They
did it by adding a thin plastic sheet around the whiskers and wrapping it
around using a metal sheath after generating nanowhiskers on (the second
electrode and outer covering). The layers were then glued together with a
special gel. Because of the insulation, the inner copper wire retains its
ability to channel energy, but the layers around the wire independently store
powerful energy.
In
other words, Thomas and his team created a supercapacitor on the outside of the
copper wire. Supercapcitors store powerful energy, like that needed to start a
vehicle or heavy-construction equipment.Although
more work needs to be done, Thomas said the technique should be transferable to
other types of materials. That could lead to specially treated clothing fibers
being able to hold enough power for big tasks. For example, if flexible solar
cells and these fibers were used in tandem to make a jacket, it could be used
independently to power electronic gadgets and other devices.
“It’s
very exciting,” Thomas said. “We take it step by step. I love getting to the
lab everyday, and seeing what we can come up with next. Sometimes things don’t
work out, but even those failures teach us a lot of things.”Yu is
the co-author of the study. He works in Thomas’ Nano Energy-Photonics Group. It
conducts research focused primarily on nanostructured supercapacitors and
Lithiuim-ion batteries, nanoarchitectured light-trapping solar cells,
photorefractive polymers for 3D display applications, and nonlinear optical
materials.Thomas
is a faculty member at the UCF Nanoscience Technology Center with joint
appointments in the College of Optics and Photonics (CREOL) and the College of
Engineering and Computer Science. He has multiple degrees including a master’s
degree in chemistry and a Ph.D. in material science. He is a recipient of
National Science Foundation’s prestigious CAREER award. He’s received media
attention over the past few years for his work on lasers and advanced
nanomaterials.
Prof. John Kurakar
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