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NEWS
INDEX
Archives
2005
February
High-intensity ultrasound
creates hollow nanospheres and nanocrystals
James E.
Kloeppel, Physical Sciences Editor
217-244-1073; kloeppel@uiuc.edu
2/22/05
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Click
photo to enlarge |
| Photo
by K.S. Suslick |
| An
SEM of a hollow nanocrystal of molybdenum oxide prepared
using high intensity ultrasound to form a layer of
amorphous material around a silica nanosphere. The
nanosphere is then dissolved away and upon heating
the shell crystallizes into a single hollow nanocrystal. |
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CHAMPAIGN,
Ill. — Using high-intensity ultrasound, researchers at the University
of Illinois at Urbana-Champaign have created hollow nanospheres and
the first hollow nanocrystals. The nanospheres could be used in microelectronics,
drug delivery and as catalysts for making environmentally friendly fuels.
“We use high-intensity ultrasound to generate nanoparticles of
molybdenum disulfide or molybdenum oxide, which bind to the surface
of tiny silica spheres that are much smaller than red blood cells,”
said Ken Suslick, the Marvin T. Schmidt Professor of Chemistry
at Illinois and a researcher at the Beckman
Institute for Advanced Science and Technology. “After heating
the spheres to produce uniform coatings, we use hydrofluoric acid to
etch away the silica, leaving hollow shells of the desired material.”
Suslick
and former postdoctoral research associate Arul Dhas describe their
work in a paper that has been accepted for publication in the Journal
of the American Chemical Society, and posted on its Web site. Funding
was provided by the National Science Foundation.
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Click
photo to enlarge |
| University
of Illinois photo |
| Chemistry
profesor Ken Suslick and colleagues used high-intensity
ultrasound to create hollow nanospheres and the first
hollow nanocrystals. The nanospheres could be used
in microelectronics, drug delivery and as catalysts
for making environmentally friendly fuels. |
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Hollow
nanospheres crafted from molybdenum disulfide could serve as a superior
catalyst for removing sulfur-containing compounds from gasoline and
other fossil fuels.
“Molybdenum-disulfide is a layered material, but its catalytic
activity occurs at its edges,” Suslick said. “By distorting
and breaking up the layers, hollow nanospheres offer increased edge-surface
area, as well as access to both inner and outer shell surfaces.”
Further processing of hollow spheres made of molybdenum oxide, however,
results in the unusual formation of hollow crystals that resemble truncated
cubes. Upon heating a second time – referred to as thermal annealing
– the hollow molybdenum oxide spheres are transformed into single-crystal
boxes with spherical hollow voids.
The sonochemical procedure could be easily applied to other material
systems to create additional types of hollow, nanostructured particles,
Suslick said.
Sonochemistry arises from acoustic cavitation – the formation,
growth and implosion of small gas bubbles in a liquid blasted with sound.
The collapse of these bubbles generates intense local heating, forming
a hot spot in the cold liquid with a transient temperature of about
9,000 degrees Fahrenheit, the pressure of about 1,000 atmospheres and
the duration of about 1 billionth of a second.
For a rough comparison, these values correspond to the temperature of
the surface of the sun, the pressure at the bottom of the ocean, and
the lifetime of a lightning strike.
Ultrasound consists of sound waves above 18,000 cycles per second, too
high-pitched to be audible to human ears.
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