Number 649, August 13, 2003
by Phillip F. Schewe, Ben Stein, and James Riordon
Detecting Plastic Explosives in Air
Detecting plastic explosives in air at the parts-per-trillion level
has been achieved by researchers at Oak Ridge National Laboratory and
the University of Tennessee (Thomas
Thundat, 865-574-6201), potentially leading to a fast, portable,
and ultrasensitive plastic-bomb "sniffer." Plastic explosives
such as pentaerythritol tetranitrate (PETN) and hexahydro-1,3,5-triazine
(RDX) pose serious threats because (1) they are easily to mold into
desired shapes, (2) they remain highly stable until detonated, and (3)
they can inflict significant damage even in small amounts. In fact,
the infamous shoe bomber had PETN in his footwear. Most current plastic-bomb
sensors are bulky and expensive. In contrast, the new sensor is a microelectromechanical
system (MEMS), or a tiny mechanical device with microscopic dimensions.
Potentially cheap and easy to mass-produce, the bomb-sniffing MEMS device
is a microcantilever, a 180-by-25-micron slab of silicon attached to
a spring-loaded wire. Similar in structure to a diving board attached
to a pool, the microcantilever is coated on one side with gold. On one
end of the gold-coated surface is a single layer of 4-MBA (4-mercaptobenzoic
acid), to which PETN and RDX both attach. Like hair that curls up on
a humid day as water molecules adsorb to it, this specially coated cantilever
will bend by significant amounts when PETN and RDX molecules attach
to it. A laser-microscope system can detect the degree of bending to
nanometer precision. Placed in a vacuum-tight glass cell, the cantilever
was exposed to a stream of ambient air with tiny traces of plastic explosive.
Using a modified atomic force microscope to measure the deflections
of the cantilever, the researchers determined that their MEMS device
could detect the explosives at a level of 14 parts per trillion, after
only 20 seconds of operation. By another measure, the device becomes
sensitive to plastic explosives even if only a few femtograms (1 fg=10-15
g) impinges upon it. A future step is to take the device out of the
laboratory and develop it into a portable sensor. While much activity
has centered on the development of sensors for detecting vapors from
all kinds of explosives, this is, to the authors' knowledge, only the
third device of its kind that uses MEMs. (Pinnaduwage
et al., Applied Physics Letters, 18 August 2003)
Barium Shield to Protect the Fetus During
CT Scans
Computed tomography (CT) on a pregnant woman's chest puts the fetus
at risk owing to the adverse effects of radiation. However, researchers
from the University of Chicago propose that it may be possible to protect
the fetus if the mother ingests barium sulfate before CT radiation exposure.
Because the fetal dose during chest scans is mainly due to internal
scatter of incident radiation, the barium compound acts as an internal
shield that absorbs errant radiation. A study that simulated a CT scan
of a pregnant woman showed that ingesting a 40 percent solution of barium
sulfate would decrease the fetal dose to a negligible level, so that
even high-quality CT imaging could be performed with minimal risk. Chester
Reft (773-702-6873) presented data from the study and discussed
the potential for barium sulfate internal shields at this week's meeting
of the American Association
of Physicists in Medicine in San Diego (Paper WE-C23A-4)
Cellophane and 3D Displays
New research on ordinary cellophane shows that it can be used to convert
a laptop screen image into a seemingly three-dimensional display. Cellophane
is birefringent: its index of refraction is not the same in all directions
in the material. This means that the polarization of an entering light
wave can be rotated. Keigo Iizuka's lab at the University of Toronto
verified that a cellophane sample 25 microns thick was better at rotating
the polarization direction of white light than a commercially available
device (called a half-waveplate) designed for a specific wavelength.
Taking advantage of the fact that light emitted from a laptop display
is naturally polarized to begin with, a 3D stereoscopic effect can be
achieved by covering half the screen with a cellophane sheet in order
to construct orthogonally polarized left and right scenes while the
viewer wears eyeglasses holding two polarizers oriented 90 degrees apart
(see
series of figures). Actually, the crossed polarizers could be suspended
between the screen and the observer, obviating the need for the viewer
to wear the glasses. According to Iizuka
(416-978-8657), this "cellography" method for producing 3D
effects will be far cheaper than those using commercially available
half-waveplates, and should be amenable to arcade gaming applications
and for medical and scientific imaging applications. Iizuka is now at
work on converting liquid crystal displays on cellular phones to 3D.
(Keigo
Iizuka, Review of Scientific Instruments, August 2003)
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