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June 26, 2006
Volume 84, Number 26
p. 10

MATERIALS SCIENCE

Nanoparticles By Design

Simulations predict wide range of geometries possible via polymer grafting

Mitch Jacoby

Nanoparticles tend to come in a limited variety of shapes, such as spheres and rods. A few researchers have succeeded in preparing nanoscale tetrapods and dumbbells. But in general, procedures for preparing nanometer-sized particles that feature exotic shapes and complex structures have not yet been developed.

TINY SHAPES Simulation results, shown here as two-dimensional maps, indicate that end-grafting immiscible polymers onto nanoparticles can lead to nanosized icosahedra (left), octahedra (right), and other complex shapes.

A new study now suggests that a wide range of nanosized polyhedra may be realizable in the future. The computational investigation predicts that grafting two types of immiscible polymers onto nanoparticles leads to phase separation among the polymer chains. The separation of phases dictates the shapes of the products, which can be tailored by controlling the relative concentrations of the polymers, chain lengths, and other polymer properties (Phys. Rev. Lett. 2006, 96, 248301). The study may lead to new types of functional materials that can be customized on the nanometer scale.

For years, researchers have known that grafting the ends of immiscible polymer chains onto flat surfaces leads to brushlike structures. The loose ends of the chains can adopt a variety of configurations that can be controlled experimentally and thereby form complex surface patterns. That idea has now been extended to spherical surfaces by Jiunn-Ren Roan, a polymer physicist at National Chung Hsing University, Taichung, Taiwan, who developed computational methods to conduct such simulations. The study indicates that phase separation can be exploited to design nanosized octahedra, icosahedra, and other complex shapes.

For example, icosahedral particles are obtained by using a 10-nm-wide particle as the grafting surface and attaching 120 chains of one type of polymer and 60 of another, with each chain measuring 20 repeat units. In contrast, grafting 30 chains each of two types of polymers that differ slightly in the number of repeat units can lead to octahedral products.

Chemical & Engineering News
ISSN 0009-2347
Copyright © 2006 American Chemical Society

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