July 25, 2005, Steve Pardo, published in Michigan Small Tech

Officials at the Fraunhofer USA Center for Coatings and Laser Applications are working with Michigan State University to bridge the gap between research and commercial applications. The center has been involved in a partnership with MSU since 2003 and provides research and development using its expertise in coating and laser technology.

Some examples of the work going on at the facility in East Lansing are carbon-based nanocoatings for a variety of applications, including microsystems. The center offers customers the integration of high performance materials into their product designs.

Fraunhofer USA is a non-profit organization and subsidiary of Fraunhofer Gesellschaft, which has 13,000 employees worldwide. “It's one of the world's largest research and development applied operations doing over $1 billion worldwide, primarily in Germany and Europe,” said Jes Asmussen, the center’s executive director and a distinguished professor at MSU.

By working together, Asmussen said, the university and Fraunhofer form an organization that is stronger than the sum of the parts. There is also work to get industry involved with the technology so research ideas can be transferred to commercial applications. The university and the company share laboratory space and have agreements for the intellectual properties.
“The integration between Fraunhofer and Michigan State has made those things possible,” said Claire Rosser, marketing manager in the Coating Technology Division of Fraunhofer. “There are MSU professors and faculty working alongside experienced engineers. The different expertise and complementary expertise help to offer truly integrated solutions to our industry partners.”
One of the more promising endeavors centers on carbon and diamond. “There are many different markets,” Asmussen said. “Diamond is sort of a magicmaterial.”

Its hardness and other properties make it ideal for coatings on a variety of items, from tools to MEMS devices. Fraunhofer developed a trademarked diamond-like carbon film called Diamor that’s used for items that receive high wear. The coating can be applied to metals, polymers, steel and glass.
Researchers can even create a diamond paper that looks like cellophane. Diamond materials could be a key in making small devices more efficient, said Thomas Schuelke, division manager of the Coating Technology Division.
The highly conductive properties of diamond can transport heat out of a device better than traditional materials. “Diamond has 10 to 15 times the heat conductivity of silicon, for example,” Schuelke said. “These are the areas we're working on here. Diamond in that sense, could be the key to solve those power density issues.”

But diamond materials are expensive to make, Asmussen said, which presently can be prohibitive for some applications. “The problem is manufacturing it at a low cost and in some cases with the proper electrical properties,” he said. “Although the market is potentially huge, on the other hand the cost of manufacturing is still relatively high. One of our activities when we synthesize diamond is to lower cost.”

For more information, please contact cclinfo@fraunhofer.org