UCF Team Tricks Solid Into Acting as
Liquid
Two scientists at the University of Central Florida have
discovered how to get a solid material to act like a liquid without
actually turning it into liquid, potentially opening a new world of
possibilities for the electronic, optics and computing industries.
When chemistry graduate student Demetrius A. Vazquez-Molina took
COF-5, a nano sponge-like, non-flammable manmade material and pressed it into
pellets the size of a pinkie nail, he noticed something odd when he looked at
its X-ray diffraction pattern. The material’s internal crystal structure
arranged in a strange pattern. He took the lab results to his chemistry
professor Fernando Uribe-Romo, who suggested he turn the pellets on their side
and run the X-ray analysis again.
The result: The crystal structures within the material fell into
precise patterns that allow for lithium ions to flow easily – like in a liquid.
The findings, published in the Journal of the
American Chemical Societyearlier this summer, are significant because a
liquid is necessary for some electronics and other energy uses. But using
current liquid materials sometimes is problematic.
For example, take lithium-ion batteries. They are among the best
batteries on the market, charging everything from phones to hover boards. But
they tend to be big and bulky because a liquid must be used within the battery
to transfer lithium ions from one side of the battery to the other. This
process stores and disperses energy. That reaction creates heat, which has
resulted in cell phones exploding, hover boards bursting into flames, and even
the grounding of some airplanes a few years ago that relied on lithium
batteries for some of its functions.
But if a nontoxic solid could be used instead of a flammable
liquid, industries could really change, Uribe-Romo said.
“We need to do a lot more testing, but this has a lot of
promise,” he said. “If we could eliminate the need for liquid and use another
material that was not flammable, would require less space and less packaging,
that could really change things. That would mean less weight and potentially
smaller batteries.”
Smaller, nontoxic and nonflammable materials could also mean
smaller electronics and the ability to speed up the transfer of information via
optics. And that could mean innovations to communication devices, computing
power and even energy storage.
“This is really exciting for me,” said Vazquez-Molina who was a
pre-med student before taking one of Uribe-Romo’s classes. “I liked chemistry,
but until Professor Romo’s class I was getting bored. In his class I learned
how to break all the (chemistry) rules. I really fell in love with chemistry
then, because it is so intellectually stimulating.”
Uribe-Romo has his high school teacher in Mexico to thank for
his passion for chemistry. After finishing his bachelor’s degree at Instituto
Tecnológico y de Estudios Superiores de Monterrey in Mexico, Uribe-Romo earned
a Ph.D. at the University of California at Los Angeles. He was a postdoctoral associate
at Cornell University before joining UCF as an assistant professor in 2013.
The findings were pursued by a team lead by Uribe-Romo in
collaboration with scientists at UCLA’s Department of Chemistry and
Biochemistry. It’s a partnership the team is pursuing to see if COF-5 is indeed
the material that could revolutionize battery and mobile device industries.
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