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Researchers Discover How to Focus
on Tiniest of the Very Small
If you need a good picture of a molecule, your first
job is getting its atoms to pose for you, says John
Silcox, Cornell's David E. Burr Professor of Engineering
and an expert in the realm of the very tiny.
But atoms are not willing subjects. They jiggle furiously,
defying any microscopist who tries to catch them at
a standstill. Nor are they polite: The larger atoms
in a molecule typically overshadow the smaller ones,
making it impossible to view the little ones.
Now, though, researchers at Cornell have developed a
technique to get a closer-than-ever look at individual
atoms within crystal molecules -- allowing them, for
the first time, to see the polarity, or physical alignment,
of those constituent atoms and to get a view of the
smaller atoms.
With the new technique, researchers can better predict
the physical properties of a crystal at every point
-- an advance that offers potential improvements in
lasers and other devices, particularly at the nanoscale,
where the structure of an individual molecule can determine
a device's behavior.
To get their new and improved view, Mkhoyan's team used
a scanning transmission electron microscope (STEM) at
IBM on samples of aluminum nitride, gallium nitride
and other crystals with particular significance in nanotechnology
research, in a chamber padded and shielded to reduce
potentially atom-jiggling acoustic noise and electromagnetic
radiation. Fitting the STEM with an aberration corrector
(a focusing device) developed at Nion Co., they directed
a 0.9 angstroms-wide electron beam at tiny crystal samples,
collecting the scattered electrons on a ring-shaped
detector and forming an image based on the resulting
scatter pattern. (An angstrom is one hundred-millionth
of a centimeter). Because larger atoms deflect electrons
at a larger angle than small ones, the resulting data
is relatively simple to interpret.
This image of a lattice crystal was captured
by Cornell researchers using a scanning transmission
electron microscope (STEM) at IBM. The yellow circles
in the center of each pear-shaped molecule represent
the stronger signal produced by a large atom; the red
portions that make up the top of each pear shape show
the weaker signal of the smaller atoms.
Used on a sample of aluminum nitride, the technique,
called annular dark imaging, shows pear-shaped molecule
columns with the larger aluminum atoms at the thicker
end and the smaller nitrogen atoms at the narrower end.
It is the first time the smaller atoms in such a structure
have been caught in an image.
The key, said Silcox, is the narrowness of the scanning
electron beam.
"We're down to the atom size, as opposed to the
atom spacing," said Silcox. "We can start
to see the light atom columns; we can characterize the
crystal very nicely and precisely, at every place on
the structure."
Mkhoyan said the inability to capture such images in
the past has been a huge hurdle for nanotechnology researchers.
"The study and application of these lattice crystals
are at the core of nanotechnology. Many papers are dedicated
to synthesis and application of the nanoparticles --
quantum dots, rods, wires, you name it -- based on these
materials," he said. "However, the performance
of the devices is highly dependent on the structural
quality of these nanoparticles.
"With our STEM annular dark field imaging, we come
to the rescue," Mkhoyan added. "We can zoom
in, pick up any region of the structure, and see how
it behaves."
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