ELECTRIC FIELD PROVIDES HANDLE TO MANIPULATE TINY PARTICLES

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ELECTRIC FIELD PROVIDES HANDLE TO MANIPULATE TINY PARTICLES
25 March 2004 - DOE/Argonne National Laboratory

Intricate patterns formed by granular materials under the influence of electrostatic fields have scientists at Argonne National Laboratory dreaming of new ways to create smaller structures for nanotechnologies.

With a combination of electric fields and fluid mixtures, researchers Igor Aronson, Maksim Sapozhnikov, Yuri Tolmachev and Wai Kwok from Argonne's Materials Science Division can cause tiny spheres of bronze and other metals to self-assemble into crystalline patterns, honeycombs, pulsating rings and bizarre two-lobed structures that whirl like tiny propellers. Such self-assembling behavior could be exploited to create the next generation nanostructures or tiny micromechanical devices. Their work has been reported in the Physical Review Letters.

The research started about four years ago, when Aronson was studying the surprisingly regular patterns formed when granular materials like sand are vibrated, seeking clues to the dynamics of such substances. "Despite about a thousand years of practical experience, we still don't completely understand granular materials," Aronson said. "They can display the properties of solids or liquids, and behaviors that defy conventional physics."

Aronson and colleagues investigated the reaction of a very fine granular materials in an electrostatic field in gases or in deep vacuum. They placed a quarter-teaspoon of 100-micron bronze spheres between two transparent sheets coated with a conducting material. Under high voltage, each bronze sphere acquires a charge from the bottom plate and is attracted to the upper sheet. The spheres reverse charge when they hit the upper sheet and are repelled back toward the lower sheet. As the process repeats 40 times per second, the bronze particles form a shimmering "gas" between the two plates. Groups of particles, responding to the electric field from the plates and from each other, tend to cluster together and coalesce into large, random groups.

Sapozhnikov, a postdoctoral researcher working under Aronson's supervision, then filled the electrostatic cell with various non-conducting fluids, including toluene, dodecane and others. The results were essentially the same as in the gas-filled cell until he tried phenetole, a colorless, oily fluid used as an ingredient in perfumes. Then came the surprise, at around 1,000 volts, the particles began to form regular patterns. By varying the voltage, the spacing between the plates and conductivity of the fluid, the researchers found they could create a regularly spaced array of dots (crystals), honeycombs and other structures. Tolmachev, an electrochemist at Material Sciences Division at Argonne, suggested that the peculiar properties of phenetole arise from the presence of free ions in this liquid. The resutls then were reproduced when ionizable compounds such as alcohol were deliberately introduced into other dielectric liquids.

“Free ions in solution interact with particles and the external electric field to create hydrodynamic forces in the liquid. These interactions create the patterns," Aronson said. "You can actually 'tune' the patterns by adding impurities to the liquid."

But the patterns aren't always static. The particles can form rings that grow, absorb other clusters of particles, then burst open. Sometimes madly spinning strange creatures are formed.

"They grow, they rotate, they do all kinds of crazy things," Aronson said. "The rotation, especially, is still not understood. The physics are complex, and we only partially understand them."

The ability of some materials to organize themselves into repeating patterns is of special interest to nanotechnologists. Tiny clusters of particles, measured in billionths of a meter, or about 1/500th the width of a human hair, exhibit different properties than their larger bulk counterparts. Argonne researchers have learned that they are more chemically reactive, exhibit new electronic properties and can be used to create materials that are stronger, tougher and more resistant to friction and wear than bulk materials.

Getting nanometer-sized particles to self-assemble into useful structures is one of the field's most difficult challenges. Self-assembly techniques are usually driven by thermodynamic forces, which dictate the type of complex pattern formation.

"This electrostatic method provides an additional way to control the self-assembly process," Aronson said. "It's another 'handle' we can use to manipulate the particles."

http://www.anl.gov

About: DOE/Argonne National Laboratory
Argonne National Laboratory is one of the US Department of Energy's largest research centres. It is also the nation's first national laboratory, chartered in 1946.

Argonne is a direct descendant of the University of Chicago's Metallurgical Laboratory, part of the World War Two Manhattan Project. After the war, Argonne was given the mission of developing nuclear reactors for peaceful purposes. Over the years, Argonne's research expanded to include many other areas of science, engineering and technology.

Today, the laboratory has about 4000 employees, including about 1200 scientists and engineers, of whom about 700 hold doctorate degrees.

Argonne occupies two sites. The Illinois site is surrounded by forest preserve about 25 miles southwest of Chicago's Loop. About 3200 of Argonne's 4000 employees work on the site's 1500 wooded acres. The site also houses the US Department of Energy's Chicago Operations Office.

Argonne-West occupies about 900 acres about 50 miles west of Idaho Falls in the Snake River Valley. It is the home of most of Argonne's major nuclear reactor research facilities. About 800 of Argonne's employees work there.

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