Carbon-70 fullerenes finally link up.

Carbon-60 fullerenes--cagelike molecules of 60 carbon atoms ([C.sub.60])--are easily coaxed into polymer chains. Trying to do the same for less-symmetrical [C.sub.70] fullerenes has proven so frustrating, however, that some scientists have speculated that it can't be done.

Never say never. In the July 27 SCIENCE, Alexander V. Soldatov, now of Harvard University Harvard University, mainly at Cambridge, Mass., including Harvard College, the oldest American college. Harvard College

Harvard College, originally for men, was founded in 1636 with a grant from the General Court of the Massachusetts Bay Colony. , and researchers in Germany, Russia, Austria, and Sweden describe how they managed the feat.

Computer modeling enabled the researchers to identify a crystal form of [C.sub.70] in which the molecules align in an orientation that could lead to polymerization polymerization

Any process in which monomers combine chemically to produce a polymer. The monomer molecules—which in the polymer usually number from at least 100 to many thousands—may or may not all be the same. .

After exposing a single crystal to high pressures and temperatures to trigger such a reaction, the researchers used spectroscopy, X-ray diffraction, and nuclear magnetic resonance nuclear magnetic resonance: see magnetic resonance.

nuclear magnetic resonance (NMR)

Selective absorption of very high-frequency radio waves by certain atomic nuclei subjected to a strong stationary magnetic field. imaging to examine the result. Their data showed that they indeed had created zigzagging polymeric chains of [C.sub.70].

This is the first time that researchers have determined the atomic positions in a fullerene fullerene, any of a class of carbon molecules in which the carbon atoms are arranged into 12 pentagonal faces and 2 or more hexagonal faces to form a hollow sphere, cylinder, or similar figure. polymer, claims Soldatov. Such molecular-scale detail might help researchers find ways to use high pressure to convert fullerenes into superhard materials Superhard materials are materials as hard as or harder than diamonds. For many decades, engineers, scientists, and corporations have sought these materials in order to machine equipment along with create new material that is more attainable with similar physical properties in order , he says.

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Author:	J.G.
Publication:	Science News
Article Type:	Brief Article
Geographic Code:	1USA
Date:	Aug 25, 2001
Words:	181
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