NEW SUPERCONDUCTING MATERIAL PACKS AN APPLIED PUNCH

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NEW SUPERCONDUCTING MATERIAL PACKS AN APPLIED PUNCH
07 March 2006 - University of Wisconsin-Madison

The jolt of excitement from the January discovery of a new high-temperature superconducting metal, magnesium diboride, may get another voltage boost this week with evidence that the material can carry electrical currents at high density.

A team of scientists from the Applied Superconductivity Center at the University of Wisconsin-Madison discovered that the material carries large currents without the common barriers seen in the ceramic superconductors in development for real-world electric power applications.

Results of the study, done in collaboration with chemist Robert Cava's research group at the Princeton University Materials Institute, are detailed in the Thursday, March 8, issue of the journal Nature.

Achieving a high critical current density has been the Achille's heel of ceramic high-temperature superconducting materials, first discovered about 15 years ago. High current densities are vital for enabling superconductivity to enter the mainstream electric utility industry, breaking out from existing medical and scientific uses.

The research team found that MgB2 is indeed capable of transporting high electrical currents, because, unlike the ceramic superconductors, the grain boundaries between crystals do not obstruct current flow.

"Our evaluation shows that this material is not just interesting scientifically, but practically as well," says David Larbalestier, principal author and ASC director. "MgB2 appears to be a good conductor with a very simple structure with only two atoms to be concerned about."

The discovery by Japanese scientists that MgB2 superconducts up to 39 degrees Kelvin (-390 degrees Fahrenheit), almost twice the temperature of any other metallic superconductor, could be a major step toward moving superconductivity from limited application to everyday use.

Superconducting materials have the ability to conduct electricity with almost no loss of energy, and are currently being tested in large demonstration motors and power cables to bring high efficiency to energy transmission.

But the essential challenge for applications of superconductivity is not just to work at higher temperatures, but to fabricate wires that carry high densities of electric current, Larbalestier says. Current has to weave and meander through billions of obstructive grain boundaries in the ceramic superconductors. Grain boundaries are interfaces a few atoms wide that separate the individual crystals of virtually all solid materials.

Because of the obstructive effects of such crystal boundaries, today's ceramic superconductors are reaching only about one-fourth to one-tenth of their potential to carry electricity across distances, Larbalestier says.

What the research team found with MgB2 was that crystal boundaries did not obstruct current, allowing high current densities to flow unimpeded. And this compound is unlikely to be the only simple metal boride that superconducts. "Sister compounds that work to higher temperatures than MgB2 probably exist and are under intense study," he adds.

The Applied Superconductivity Center is in a unique position to study superconducting materials because it has a broad multi-disciplinary capability for doing both basic and applied studies of superconducting materials. One crucial capability is that of magneto-optical imaging, a technique brought from Russia by ASC scientist Anatoly Polyanskii, which allows the precise flow of electricity through the material to be visualized in fine detail.

News of the Japanese discovery spread like wildfire in late January through e-mail between center staff and alumni well before results were public. In late January, Larbalestier and UW-Madison materials science professor Eric Hellstrom decided to make the new material. The very next day, Cava's Princeton research team called to say they had samples of MgB2.

"He sent us the sample and the students, staff and postdocs just went at it night and day," Larbalestier says.

A flurry of work is rapidly defining the applied potential of this very surprising discovery, not yet two months old. Teams led by Hellstrom and materials science Professor Chang-Beom Eom already have created wires and thin films from the material. UW-Madison physics Professor Mark Rzchowski's group is studying the basic physics of the superconducting mechanism, while materials science Professor Susan Babcock's team is studying its atomic structure using transmission electron microscopy.

These studies will be part of a special session of the American Physical Society meeting has been set for Monday, in Seattle, which will include about 60 presentations worldwide.

ASC projects are supported by the Air Force Office of Scientific Research, the Department of Energy and the National Science Foundation, through its Materials Research Science and Engineering Center.

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About: University of Wisconsin-Madison
In achievement and prestige, the University of Wisconsin-Madison has long been recognized as one of America’s great universities. A public, land-grant institution, UW-Madison offers a complete spectrum of liberal arts studies, professional programs and student activities. Many of its programs are hailed as world leaders in instruction, research and public service.

The university traces its roots to a clause in the Wisconsin Constitution, which decreed that the state should have a prominent public university. In 1848, Nelson Dewey, Wisconsin’s first governor, signed the act that formally created the university, and its first class, with 17 students, met in a Madison school building on February 5, 1849.

From those humble beginnings, the university has grown into a large, diverse community, with about 40,000 students enrolled each year. These students represent every state in the nation, as well as countries from around the globe, making for a truly international population.

UW-Madison is the oldest and largest campus in the University of Wisconsin System, a statewide network of 13 comprehensive universities, 13 freshman-sophomore transfer colleges and an extension service. One of two doctorate-granting universities in the system, UW-Madison’s specific mission is to provide "a learning environment in which faculty, staff and students can discover, examine critically, preserve and transmit the knowledge, wisdom and values that will help insure the survival of this and future generations and improve the quality of life for all."

The university achieves these ends through innovative programs of research, teaching and public service. Throughout its history, UW-Madison has sought to bring the power of learning into the daily lives of its students through innovations such as residential learning communities and service-learning opportunities. Students also participate freely in research, which has led to life-improving inventions from more fuel-efficient engines to cutting-edge genetic therapies.

Students, faculty and staff are motivated by a tradition known as the "Wisconsin Idea," described by UW President Charles Van Hise in 1904 as the compelling need to carry "the beneficent influence of the university ... to every home in the state." The Wisconsin Idea permeates the university’s work and helps forge close working relationships among university faculty and students and the state’s industries and government.

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