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Doe Awards Nist Millions of Supercomputing Hours, Aims For 'concrete Results'

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rheometer flow simulation

This simulation depicts flow in a rheometer. Such simulations can provide insight into physical mechanisms that control particle dispersion and mixing.

Credit: NIST

When you spot laborers pouring concrete for a new building or bridge, it may not occur to you that they are working with a substance so complex that it requires the world's most powerful computers to understand its behavior. But the U.S. Department of Energy (DOE) has just awarded a team of computer scientists, physicists and mathematicians at the National Institute of Standards and Technology (NIST) millions of hours of supercomputing time to analyze concrete flow, in the hope that this common material can be improved.

A full list of INCITE program 2011 awards of 1.7 billion hours on DOE supercomputers is available online.

The DOE's INCITE award to the NIST team provides up to 75 million "processor hours" over three years on the IBM Blue Gene/P computer at Argonne National Laboratory near Chicago; the first year provides 25 million hours. One hour is equivalent to one computer processor crunching numbers for 60 minutes, and the Argonne machine contains many thousands of processors that can run in parallel.

The team's aim is to simulate and analyze the movement and interaction among the many particles and fluids that comprise unset concrete—by no means an easy task. The particles vary widely in size—from large stones to grains of sand—and the fluid in which they are suspended flows in ways that change depending on the pressure during stirring and mixing.

All in all, it's a heap of mathematical trouble to model such a material, so why bother? Concrete's use stretches back millennia, but modern additives make it possible to create concrete that is not only strong but translucent, flexible, or possessing a number of other qualities that make it as valuable to today's architects as to ancient Rome's. There's a $100 billion industry in concrete in the United States alone, making it critical to stir up the best concrete possible to improve the infrastructure.

"You can mix in materials to make concrete better, but right now choosing these additives is based largely on guesswork. We'd like to be able to improve it intelligently," says NIST's William George. "This is by far the largest supercomputing project that NIST has ever taken on in terms of time and processing power, and we hope it will provide the world with more long-lasting, sustainable concrete."


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