New Law for Superconductors
Mathematical description of relationship between thickness,
temperature, and resistivity could spur advances.
By Larry Hardesty | MIT News Office, December 16, 2014
Mathematical description of relationship between thickness,
temperature, and resistivity could spur advances.
By Larry Hardesty | MIT News Office, December 16, 2014
MIT researchers have discovered a
new mathematical relationship — between material thickness, temperature, and
electrical resistance — that appears to hold in all superconductors. They
describe their findings in the latest issue of Physical Review B.
The result could shed light on the
nature of superconductivity and could also lead to better-engineered
superconducting circuits for applications like quantum computing and
ultralow-power computing.
“We were able to use this knowledge
to make larger-area devices, which were not really possible to do previously,
and the yield of the devices increased significantly,” says Yachin Ivry, a
postdoc in MIT’s Research Laboratory of Electronics, and the first author on
the paper.
Ivry works in the Quantum
Nanostructures and Nanofabrication Group, which is led by Karl Berggren, a professor
of electrical engineering and one of Ivry’s co-authors on the paper. Among
other things, the group studies thin films of superconductors.
Superconductors are materials that,
at temperatures near absolute zero, exhibit no electrical resistance; this
means that it takes very little energy to induce an electrical current in them.
A single photon will do the trick, which is why they’re useful as quantum
photodetectors. And a computer chip built from superconducting circuits would,
in principle, consume about one-hundredth as much energy as a conventional
chip.
“Thin films are interesting
scientifically because they allow you to get closer to what we call the
superconducting-to-insulating transition,” Ivry says. “Superconductivity is a
phenomenon that relies on the collective behavior of the electrons. So if you
go to smaller and smaller dimensions, you get to the onset of the collective
behavior.”
Vexing variation
Specifically, Ivry studied niobium
nitride, a material favored by researchers because, in its bulk form, it has a
relatively high “critical temperature” — the temperature at which it switches
from an ordinary metal to a superconductor. But like most superconductors, it
has a lower critical temperature when it’s deposited in the thin films on which
nanodevices rely.
Previous theoretical work had
characterized niobium nitride’s critical temperature as a function of either
the thickness of the film or its measured resistivity at room temperature. But
neither theory seemed to explain the results Ivry was getting. “We saw large
scatter and no clear trend,” he says. “It made no sense, because we grew them
in the lab under the same conditions.”
So the researchers conducted a
series of experiments in which they held constant either thickness or “sheet resistance,”
the material’s resistance per unit area, while varying the other parameter;
they then measured the ensuing changes in critical temperature. A clear pattern
emerged: Thickness times critical temperature equaled a constant — call it A —
divided by sheet resistance raised to a particular power — call it B.
After deriving that formula, Ivry
checked it against other results reported in the superconductor literature. His
initial excitement evaporated, however, with the first outside paper he
consulted. Though most of the results it reported fit his formula perfectly,
two of them were dramatically awry. Then a colleague who was familiar with the
paper pointed out that its authors had acknowledged in a footnote that those
two measurements might reflect experimental error: When building their test
device, the researchers had forgotten to turn on one of the gases they used to
deposit their films.
Broadening the scope
The other niobium nitride papers
Ivry consulted bore out his predictions, so he began to expand to other
superconductors. Each new material he investigated required him to adjust the
formula’s constants — A and B. But the general form of the equation held across
results reported for roughly three dozen different superconductors.
It wasn’t necessarily surprising
that each superconductor should have its own associated constant, but Ivry and
Berggren weren’t happy that their equation required two of them. When Ivry
graphed A against B for all the materials he’d investigated, however, the
results fell on a straight line.
Finding a direct relationship
between the constants allowed him to rely on only one of them in the general
form of his equation. But perhaps more interestingly, the materials at either
end of the line had distinct physical properties. Those at the top had highly
disordered — or, technically, “amorphous” — crystalline structures; those at
the bottom were more orderly, or “granular.” So Ivry’s initial attempt to
banish an inelegance in his equation may already provide some insight into the
physics of superconductors at small scales.
“None of the admitted theory up to
now explains with such a broad class of materials the relation of critical
temperature with sheet resistance and thickness,” says Claude Chapelier, a
superconductivity researcher at France’s Alternative Energies and Atomic Energy
Commission. “There are several models that do not predict the same things.”
Chapelier says he would like to see
a theoretical explanation for that relationship. But in the meantime, “this is
very convenient for technical applications,” he says, “because there is a lot
of spreading of the results, and nobody knows whether they will get good films
for superconducting devices. By putting a material into this law, you know
already whether it’s a good superconducting film or not.”
No comments:
Post a Comment