Engineering prof helping to boost capabilities of leading national research center

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Engineering prof helping to boost capabilities of leading national research center

Engineering prof helping to boost capabilities of leading national research center

Posted: September 21, 2011

New imaging facility will provide deeper knowledge about fundamental nature of materials

An Arizona State University engineering professor and collaborators at Argonne National Laboratory are working to pave the way to study technologically important materials in more revealing ways than ever before.

They are playing an important role in expanding the capabilities of Argonne with development of an innovative facility for high-energy X-ray tomography research.

ASU engineering professor Nik Chawla is working with colleagues to develop new research facilities at Argonne National Laboratory that will provide closer looks at the microstructures of materials. The new knowledge is expected to aid development of ways to strengthen materials used in everything from athletic shoes and cables to aircraft, automobiles and a broad array of devices and electronics components. It will also yield knowledge about how to fortify materials used to build bridges, dams and similar structures, making them more resistant to materials defects that lead to structural failures.

The high-energy X-ray synchrotron tomography X-ray beamline “will provide major improvements in the performance of X-ray sources that will allow us to gain new insights into potential solutions to some of the most fundamental problems of science and engineering,” said Nik Chawla, professor of materials science and engineering in the School for Engineering of Matter, Transport, and Energy, one of ASU’s Ira A. Fulton Schools of Engineering.

The facility will be one part of an upgrade to enhance the capacity and capabilities of the Advanced Photon Source at Argonne, one of the nation’s most prominent science and engineering centers.

Argonne, located near Chicago, is the oldest U.S. Department of Energy (DOE) national laboratory. Its Advanced Photon Source is one of five national synchrotron light- source research facilities operated by the DOE’s Office of Science.

On Sept. 15, William Brinkman, director of the DOE Office of Science, approved Critical Decision 1 for the Advanced Photon Source upgrade.

The decision formally approves the alternative selection and cost range for the upgrade, establishing the preliminary technical scope of the project and authorizing the detailed preliminary design, as well as initial research and development activities. Funding for the project will be subject to congressional appropriations.

Chawla and Francesco De Carlo, leader of the X-ray Imaging Group in the Argonne X-ray Science Division at the Advanced Photo Source facility, have been at the helm of a team of engineers and scientists making the case to the energy department’s science office officials about the benefits the nation could reap by investing in the advanced tomography research technology.

The international team led by Chawla and De Carlo includes engineers and scientists from the Nanjing Institute of Geology and Paleontology in China; the University of Melbourne and Monash University, both in Australia; the University of Maryland; and East Tennessee State University – as well as researchers at Argonne.

Chawla said the tomography facility promises to provide insights into ways to improve materials used in aircraft, automobiles, ships, and a broad array of other vehicles, devices and electronics components.

It will also yield knowledge to help engineers design bridges, dams and similar structures that are more resistant to materials defects that lead to structural failures.

In addition, he said, the new imaging technology will allow geologists and paleontologists to perform more intricate examinations of rocks and fossils – enabling them to uncover more revealing information about the Earth’s natural history and evolution.

“Before, we could look only so deep.  You needed thin slices or very small pieces of materials if you wanted to get clear imaging of their basic microstructures,” Chawla explained.

“Now we will be able to penetrate much larger and thicker specimens. We can handle materials of larger sizes, volumes, and higher density. More importantly we can now see changes to the microstructures in real time, in three dimensions, to examine more precisely what occurs when the materials are exposed to thermal or mechanical stimuli,” he said.

The new imaging capabilities will also allow researchers to better predict how materials will behave over time under various kinds of pressure, stress and climate conditions.

Through Chawla, ASU will have an important role in developing future research avenues for the new X-ray tomography facility. Leading research institutions from around the world are expected to make requests to use the new facility.

(480) 965-8122
Ira A. Fulton Schools of Engineering

About The Author

Joe Kullman

Before coming to ASU in 2006 as the first senior media relations officer for the Ira A. Fulton Schools of Engineering, Joe had worked as a reporter, writer and editor for newspapers and magazines dating back to the dawn of the age of the personal computer. He began his career while earning a bachelor’s degree in journalism and a master’s degree in philosophy from Kent State University in Ohio. Media Contact: joe.kullman@asu.edu | (480) 965-8122 | Ira A. Fulton Schools of Engineering Communications

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