Number 527, February 23, 2001 by Phil
Schewe, James Riordon, and Ben Stein
Silicon Cage Clusters: Better Than Buckyballs?
The discovery
of carbon fullerenes (Update
2) caught the imagination of scientists and the public alike as
researchers raced to find applications for the tiny spheres commonly
called buckyballs. Now researchers at the Joint Research Center for
Atom Technology have managed to create similar arrangements of silicon
atoms, a feat previously thought impossible owing to silicon's chemical
nature. Potential applications of the silicon assemblies range from
components in quantum computers to chemical catalysts to new superconducting
compounds.
Silicon is, of
course, a vital material for the vast semiconductor industry and one
of the most studied elements in all of science. Therefore this new discovery
might lead to applications that could match or even exceed those expected
for carbon fullerenes. Unlike carbon atoms, pure silicon cannot form
stable, closed cages. The new research, however, reveals that silicon
can gather around a central metal atom and settle into basket-like arrangements
called silicon cage clusters. One particularly low energy, and therefore
stable, configuration consists of twelve silicon atoms forming a regular,
hexagonal cage that surrounds a tungsten atom (see figure at Physics
News Graphics).
Because the choice
of a central metal atom affects the chemical behavior of cage clusters,
scientists should be able to tailor the clusters to create novel nanodevices
and catalysts. The researchers (Hidefumi Hiura, h-hiura@bq.jp.nec.com, 011-81-298-50-2615)
note in particular that clusters efficiently isolate their guest metal
atoms from the surrounding environment, a characteristic that could
permit a cluster to act as a robust qubit in a quantum computer by storing
a single bit of information in the spin state of the enclosed metal
atom. (H. Hiura
et al, Physical Review Letters, 26 February 2001; text at
Physics News Select.)
Untying the Knot
Dealing with shoelaces
is for most of us the first exposure to knots. Neckties, sailor hitches,
twist-ties, and polymers are some of the other things that knot. To
see how knots untie themselves, scientists at Los Alamos have studied
model polymers made from 2-mm steel balls linked by thin rods. These
chains, consisting of up to 300 beads, were laid in a pan, tied in knots
that allows for three cross-over points, and then shaken (see figures
at Physics News Graphics).
The rods allowed
the shaking chain to stretch and bend, and hence to "explore"
many conformations on its way toward untying itself. The unknotting
time, not surprisingly, is proportional to the square of the chain length.
What is surprising is that although the chain motion is complicated,
the unknotting time depends only on the three crossing points, whose
motions resemble a random-walk process, except that the points may not
coincide.
According to Eli
Ben-Naim (505-667-9471, ebn@lanl.gov)
this type of shaking experiment represents a new way to study structures
in granular materials and the dynamics of entanglements in DNA and other
polymers. (Ben-Naim et al., Physical Review Letters, 19 February
2001; text at Physics News
Select).
Permian Catastrophe Comet?
A trace of iridium
in geological records around the world corresponding to the time just
between the Cretaceous and Tertiary eras 60 million years ago has generally
been interpreted as evidence of a catastrophic meteor strike leading
to the extinction of many species, including the dinosaurs. Could such
an event have led to the even greater extinctions that occurred during
the Permian era 250 million years ago? New forensic evidence seems to
point in that direction. Geologic samples in Japan and China, this time
from the Permian era, reveal C60 molecules bearing an anomalous ratio
of helium-3 to helium-4 atoms, suggesting an extra-terrestrial origin.
(Science, February 23,
2001.)
Correction
The "C"
in the BCS theory (Update 526) corresponds to
Leon (not Bernard) Cooper.
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