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© KIM KULISH/CORBIS |
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ESCAPE
THE HEAT: A new liquid crystal and butyl rubber suit could
keep soldiers cool while still protecting them from chemical warfare
agents. |
In this age of looming bioterrorism, keeping
chemical warfare vapors off of soldiers is a primary military concern.
A group of Colorado scientists may have just come up
with a solution
that can keep troops safe while giving them the comfort of
breathability.
In the past, military personnel had two choices: they
could wear a
breathing apparatus along with a full-body suit of cross-linked butyl
rubber, or a garment fortified with activated carbon. Although the
latter could adsorb any harmful aerosols floating their way, it was
heavy--imagine wearing an outfit with charcoal stuffed in every
pocket--and the carbon needed to be periodically replaced. As for the
garment made of rubber, the same material used in hockey pucks and most
waterproof clothing, it kept most agents out, but it also locked the
soldier's sweat in--leading to heatstroke or even death, in some
extreme cases.
Butyl rubber, a linear polymer, "is a really good
barrier," says
University of Colorado at Boulder chemist Douglas L. Gin, "but it's
really good both ways."
Gin, along with Brian Elliott, a researcher at
TDA Research in Wheat
Ridge, Colo., led a team that sought to tweak
butyl rubber for greater water transport through the material. In order
to get butyl rubber into a state useful for a suit, the linear polymer
must be cross-linked to make a three-dimensional network, which,
according to Gin, "makes it more chemically, mechanically and thermally
robust."
The researchers blended butyl rubber with liquid
crystals that
could be organized to form hydrophilic, 1.2-nanometer-wide pores. These
holes would allow water to pass through, but they would block chemical
agents that were either too big to fit or were hydrophobic and
therefore repelled by the pores. Unfortunately, when testing the new
material with water vapor and 2-chloroethyl ethyl sulfide (CEES or
"half mustard" gas), Gin and Elliott discovered that water vapor moved
across the membrane, but not at a rate that would be acceptable for
military use.
So the team went back to the drawing board, using
a new liquid crystal that created, rather than pores, a "bicontinuous
cubic" made up of interconnected, three-dimensional sheets.
"The first version was just pipes," explains Gin. "It's
really
easy to block a pipe--all you have to do is plug it somewhere in the
middle and transport is completely stopped." With the second version,
"it now is more like intercrisscrossing layers of water in three
dimensions. So you get easy transport no matter which way water wants
to go in or out."
Sure enough, when the scientists tested the water vapor
transport rate for a four-micrometer-thick film of their new material,
it performed at four times the minimum acceptable rate by the military
and 300 times that of plain, cross-linked butyl rubber. It is also
about 30 percent less permeable to CEES, making it more effective for
protection against a chemical agent.
Gin and Elliott are now working to make their new,
improved
butyl rubber as effective at thinner swaths. They also believe they may
be able to use the material not only in suits, but as filters for
solutions from brine to contaminated water.
"The crux of our whole technology is we can take
conventional
commercial butyl rubber and, by blending it with our polymerizable
liquid crystal, we can actually make these water conduits in there,"
Gin remarks. "And depending on the type of liquid crystals, we can
control the dimensionality from one-dimensional cylinders or tubes to
the much more effective interconnected 3-D water manifold system." --Nikhil
Swaminathan
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SCIENCE NEWS