NIST laser-based method cleans up grubby nanotubes
Before carbon nanotubes can fulfill their promise
as ultrastrong fibers, electrical wires in molecular devices, or
hydrogen storage components for fuel cells, better methods are needed
for purifying raw nanotube materials. Researchers at the National
Institute of Standards and Technology (NIST) and the National
Renewable Energy Laboratory (NREL, Golden, Colo.), have taken a step
toward this goal by demonstrating a simple method of cleaning
nanotubes by zapping them with carefully calibrated laser pulses.
Before and after electron microscope images of a pyroelectric
detector coated with single-walled nanotubes (SWNTs) visually
demonstrate the effect of the laser cleaning process. In addition,
the SWNTs look visibly blacker after laser treatment, suggesting
less graphitic material and increased porosity.
When carbon nanotubes - the cylindrical form
of the fullerene family - are synthesized by any of several processes,
a significant amount of contaminants such as soot, graphite and other
impurities also is formed. Purifying the product is an important issue
for commercial application of nanotubes. In a forthcoming issue of
Chemical Physics Letters*, the NIST/NREL team describes how pulses
from an excimer laser greatly reduce the amount of carbon impurities
in a sample of bulk carbon single-walled nanotubes, without destroying
tubes. Both visual examination and quantitative measurements of
material structure and composition verify that the resulting sample is
"cleaner." The exact cleaning process may need to be slightly modified
depending on how the nanotubes are made, the authors note. But the
general approach is simpler and less costly than conventional "wet
chemistry" processes, which can damage the tubes and also require
removal of solvents afterwards.
"Controlling and determining tube type is sort of
the holy grail right now with carbon nanotubes. Purity is a key
variable," says NIST physicist John Lehman, who leads the research. "Over
the last 15 years there's been lots of promise, but when you buy some
material you realize that a good percentage of it is not quite what
you hoped. Anyone who thinks they're going into business with
nanotubes will realize that purification is an important - and
expensive - step. There is a lot of work to be done."
The new method is believed to work because, if
properly tuned, the laser light transfers energy to the vibrations and
rotations in carbon molecules in both the nanotubes and contaminants.
The nanotubes, however, are more stable, so most of the energy is
transferred to the impurities, which then react readily with oxygen or
ozone in the surrounding air and are eliminated. Success was measured
by examining the energy profiles of the light scattered by the bulk
nanotube sample after exposure to different excimer laser conditions.
Each form of carbon produces a different signature. Changes in the
light energy as the sample was exposed to higher laser power indicated
a reduction in impurities. Before-and-after electron micrographs
visually confirmed the initial presence of impurities (i.e., material
that did not appear rope-like) as well as a darkening of the nanotubes
post-treatment, suggesting less soot and increased porosity.
The researchers developed the new method while
looking for quantitative methods for evaluating laser damage to
nanotube coatings for next-generation NIST standards for optical power
measurements. The responsivity of a prototype NIST standard increased
5 percent after the nanotube coating was cleaned.
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