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NIST Scientists Use Electron Beam
to Unravel the Secrets of an “Atomic Switch”
Scientists at the Commerce Department’s
National Institute of Standards and Technology (NIST)
have used a beam of electrons to move a single atom
in a small molecule back and forth between two positions
on a crystal surface, a significant step toward learning
how to build an “atomic switch” that turns
electrical signals on and off in nanoscale devices.
"It’s still futuristic to talk about a real
atomic switch but we’re getting closer,”
says physicist Joseph Stroscio, lead author of the paper.
In addition, by applying the findings to nanoscale fabrication
on semiconductors and insulating thin films, it may
be possible to develop new classes of electronic and
magnetic devices constructed atom by atom.
NIST physicists used a custom-built, cryogenic scanning
tunneling microscope (STM)—which provides a voltage
and beam of electrons at its needle-like tip—to
perform several different types of atomic scale measurements
and manipulations. NIST theorists performed calculations
of the atoms’ electronic structure, which confirmed
the experimental results.
A molecular chain of one cobalt atom and several copper
atoms set upon a surface of copper atoms was constructed
atom by atom using the STM in an atom manipulation mode.
Then the STM was used to shoot electrons at the molecular
chain and its effect on the switching motion of the
cobalt atom was measured.
NIST researchers used
a scanning tunneling microscope (STM) to move a single
cobalt atom (blue sphere) in a small molecule back and
forth between two positions on a crystal surface.
In addition, the team used a “tunneling
noise spectroscopy” technique to determine how
long the atom stays in one place. This measurement method
was developed by two of the authors based on their 2004
discovery that an atom emits a characteristic scratching
sound when an STM is used to move the atom between two
types of bonding sites on a crystal.
“The two most important new findings,” Stroscio
says, “are an increased understanding of the science
behind atomic switching and the development of a new
measurement capability to spatially map the probability
of an electron exciting the desired atom motion.”
The scientists analyzed what happened to the atom-switching
rate as changes occurred in the STM voltage and in the
current between the STM tip and surface. Above a threshold
voltage of about 15-20 millivolts, the probability for
switching per electron is constant, meaning that the
electrons contain sufficient energy to move the cobalt
atom. Higher currents result in faster switching.
The data suggested that a single electron boosts the
molecule above a critical energy level, allowing a key
bond to break so the cobalt atom can switch positions.
The cobalt atom was less likely to switch as the molecular
chain was extended in length from two to five copper
atoms, demonstrating that the atom switching dynamics
can be tuned through changes in the molecular architecture.
The researchers also found that the position of the
STM tip is critical. They made this discovery by recording
detailed noise measurements of the molecule with atomic
scale resolution. An analysis of the noise enabled the
team to make a spatial map of the switching speed and
probability, showing that switching is most likely when
the STM tip is positioned to the left of the cobalt
atom.
“This insight raises the possibility that molecular
orbital analysis may be used to guide the design and
control of single atom manipulation in nanostructures,”
the authors write.
The work was supported in part by the Office of Naval
Research.
Visit http://cnst.nist.gov
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