This is actually
interesting. They were able to determine the triple point in solid Vanadium
Dioxide against pretty long odds. I do
not know if this methodology can be reasonably applied to other compounds
though.
It should also
lead to a better understanding to the internal structure of the triple point
phenomena now that we have brought one into the lab to look at.
All nice work
representing many rears of effort.
Physicists
pinpoint key property of material that both conducts and insulates
by Staff Writers
Seattle WA (SPX) Aug 26, 2013
The lines of data points are where two of the three solid-state phases of vanadium dioxide can exist stably together, and the point where the three lines meet - the triple point - is where all three phases can exist together. Image courtesy David Cobden/UW.
It is well known to scientists that the three common
phases of water - ice, liquid and vapor - can exist stably together only at a
particular temperature and pressure, called the triple point.
Also well known is that the solid form of many
materials can have numerous phases, but it is difficult to pinpoint the
temperature and pressure for the points at which three solid phases can coexist
stably.
Scientists now have made the first-ever accurate
determination of a solid-state triple point in a substance called vanadium
dioxide, which is known for switching rapidly - in as little as one
10-trillionth of a second - from an electrical insulator to a conductor, and
thus could be useful in various technologies.
"These solid-state triple points are fiendishly
difficult to study, essentially because the different shapes of the solid
phases makes it hard for them to match up happily at their interfaces,"
said David Cobden, a University of Washington physics professor.
"There are, in theory, many triple points
hidden inside a solid, but they are very rarely probed."
Cobden is the lead author of a paper describing the
work, published Aug. 22 in Nature.
In 1959, researchers at Bell Laboratories discovered
vanadium dioxide's ability to rearrange electrons and shift from an insulator
to a conductor, called a metal-insulator transition. Twenty years later it was
discovered that there are two slightly different insulating phases.
The new research shows that those two insulating
phases and the conducting phase in solid vanadium dioxide can coexist stably at
65 degrees Celsius, give or take a tenth of a degree (65 degrees C is equal to
149 degrees Fahrenheit).
To find that triple point, Cobden's team stretched
vanadium dioxide nanowires under a microscope. The team had to build an
apparatus to stretch the tiny wires without breaking them, and it was the
stretching that allowed the observation of the triple point, Cobden said.
It turned out that when the material manifested its
triple point, no force was being applied - the wires were not being stretched
or compressed.
The researchers originally set out simply to learn
more about the phase transition and only gradually realized that the triple
point was key to it, Cobden said. That process took several years, and then it
took a couple more to design an experiment to pin down the triple point.
"No previous experiment was able to investigate
the properties around the triple point," he said.
He regards the work as "just a step, but a
significant step" in understanding the metal-insulator transition in
vanadium dioxide. That could lead to development of new types of electrical and
optical switches, Cobden said, and similar experiments could lead to
breakthroughs with other materials.
"If you don't know the triple point, you don't
know the basic facts about this phase transition," he said. "You will
never be able to make use of the transition unless you understand it
better."
Co-authors are UW physics graduate students Jae
Hyung Park, T. Serkan Kasirga and Zaiyao Fei; undergraduates Jim Coy and Scott
Hunter; and postdoctoral researcher Chunming Huang. The work was funded by the
U.S. Department of Energy.
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