This development is important for the long-term storage of plutonium, an issue of worldwide concern. As stockpiles of plutonium-based nuclear weapons age, their reliability and safety come into question.

In a paper appearing in the April 11 issue of the journal Nature, Rutgers' Sergej Y. Savrasov, a postdoctoral associate; Gabriel Kotliar, professor of physics; and Elihu Abrahams, director of the Center for Materials Theory, present a novel electronic structure method for predicting stability changes in plutonium, potentially a landmark achievement in solid-state physics.

Plutonium is regarded even by scientists as a complex and mysterious element, rarely occurring in nature, and made artificially for the first time in 1940.

"Just as water has phases ­- liquid, solid and gaseous ­- so does plutonium," explained Kotliar. "In plutonium, there are many more solid phases, ranging from a dense and unstable alpha phase to a much more extended and stable delta phase.

"While the search for answers about plutonium phases generally has been through experimental methods, we employed analytical and computer calculations to predict changes in the structure of the solid states of plutonium," said Kotliar. "We felt a strong need for theoretical methods that are accurate. This element is far too toxic for extensive experimental procedures in the laboratory, and the use of theoretical methods is mandatory if we are to deal with problems over long time scales. Experimental methods do not work for predicting changes 100 years into the future."

In developing its new method, the team employed Rutgers' High-Performance Computing Cluster, a computational grid comprising more than 80 computer processors configured as a distributed resource, and a Department of Energy supercomputer.

The researchers can now predict volume and stability changes in plutonium while gaining insights into where and when the transition between the alpha and delta phases occurs and under what conditions.

"We are dealing with an extremely delicate balance between the two phases, and which one wins and when this happens is information that is necessary to assure the safe storage of this important material," added Kotliar.

The paper in Nature is titled "Correlated Electrons in d-Plutonium within a Dynamical Mean-Field Picture" by S. Y. Savrasov, G. Kotliar, E. Abrahams, Department of Physics and Astronomy and Center for Materials Theory, Rutgers University, Piscataway, N.J.

The work presented in the paper was supported by the Department of Energy Division of Basic Energy Sciences and by Los Alamos National Laboratory. - By Joseph Blumberg

[Contact: Gabriel Kotliar, Sergej Savrasov, Joseph Blumberg]

12-Apr-2001