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Colorized SEM image of a
suspended graphene resonator. (inset) Schematic of the resonator.
The graphene is in contact with a gold electrode that can be used
to electrostatically actuate the resonator. A red laser is used to
detect the motion of the resonator by laser interferometry.
Image by Arend van der Zande and
Scott Bunch |
Creating a sheet of cohesive material just one
atom thick is impossible with most substances; most ball up or
disintegrate as they are shaved into ever-thinner slices. Carbon,
though, is unique: in diamonds, its covalent bonds form nature's
hardest substance. And as graphite, it bonds tightly in a
two-dimensional plane but very loosely in the third dimension. So
sloughing off a few layers is as easy as writing with a pencil.
Bunch etched a silicon dioxide wafer with tiny
trenches, each about 1 micron (a millionth of a meter) wide and 300
nanometers (a nanometer is a billionth of a meter) deep. He spread a
light layer of graphite over the wafer simply by gluing a chunk of it
onto a toothpick and writing on the wafer's surface. Using an optical
microscope, he then identified trenches that were spanned by very thin
layers (each tens of thousands of atoms across) of graphene sheets (the
term for single-atom-thick sheets of graphite).
Using atomic force microscopy, which measures the
amount of deflecting force a tiny cantilever experiences as it scans
nanometers over the surface of a specimen, Bunch and colleagues
determined the thickness of the layers (number of graphene sheets)
that spanned the trenches. Raman spectroscopy, a technique that
measures the way a substance scatters monochromatic light, confirmed
that several trenches were spanned by single sheets of graphene. By
delivering a tiny current to the single-atom bridges and using a laser
to detect their vibrations, Bunch's group could determine the
stiffness of the material.
"How fast they vibrate is a function of how thick
they are, how long they are and how stiff the material itself is,"
Bunch said. "It turns out that graphene is one of the stiffest
materials around."
It's also ultrathin and light, which might make it
valuable as an extremely sensitive scale for tiny masses or a gauge
for pressure differences.
And it's simple. "These are basically the thinnest
vibrating structures you can have," said Bunch. "So it's surprising
that they're so easy to make." |
