IBM and LLNL Scientists Show Supercomputer Advance in Predicting Materials Strength.Business Editors/High Tech Writers SAN JOSE, Calif.--(BUSINESS WIRE)--April 29, 2002 "Computational microscope" can aid understanding of fracture, from small crystals to large earthquakes An unprecedented billion-atom calculation has enabled a team of IBM (International Business Machines Corporation, Armonk, NY, www.ibm.com) The world's largest computer company. IBM's product lines include the S/390 mainframes (zSeries), AS/400 midrange business systems (iSeries), RS/6000 workstations and servers (pSeries), Intel-based servers (xSeries) and Lawrence Livermore National Laboratory Lawrence Livermore National Laboratory: see Lawrence Berkeley National Laboratory. (body) Lawrence Livermore National Laboratory - (LLNL) A research organaisatin operated by the University of California under a contract with the US Department of Energy. (LLNL LLNL - Lawrence Livermore National Laboratory ) scientists to demonstrate a major advance in using supercomputers to simulate the strength of materials strength of materials, measurement in engineering of the capacity of metal, wood, concrete, and other materials to withstand stress and strain. Stress is the internal force exerted by one part of an elastic body upon the adjoining part, and strain is the deformation . Using one of the world's most powerful supercomputers as a computational microscope, the scientists can peer deep inside simulated materials to reveal how they break, as well as what makes them strong or weak, stiff or flexible. Calculating the strength of new materials is a critical issue in creating structures as small as microprocessors -- or as large as buildings or airplanes -- that will withstand real-world forces. The scientists' results are also a major step toward using supercomputers to design new materials with customized properties, such as their levels of strength, hardness and toughness. "The sudden unexpected fracture of a material can have devastating consequences, such as during an earthquake or the failure of an airplane structure," said Farid F. Abraham Abraham earned his Bachelor of Science and Ph.D from the University of Arizona in 1959 and 1962, respectively. By pioneering new methods of using computer modelling in research, he has made seminal contributions to science in the fields of fracture mechanics, membrane dynamics and phase , the researcher from IBM's Almaden Research Center The IBM Almaden Research Center, located near San Jose, California, is one of IBM's largest research centers, specializing in both basic research in material science and applied research in computer storage, where many refinements and improvements were made in hard disc drive in San Jose, Calif., who led the team effort. "Today's supercomputers and our innovative software allow us to understand their properties much better and how they deform and break." In the most extensive computer calculations of their type to date, the scientists used the ACSI ACSI Association of Christian Schools International ACSI American Customer Satisfaction Index ACSI Association Canadienne des Sciences de l'Information (French) ACSI American Communications Services, Inc. White supercomputer, which was built last year by IBM for LLNL, to create and then deform simulated cubes of as many as 1 billion atoms. Creative computer visualization techniques revealed the inner workings of the atoms' response to the stress: stunning images and videos showing cracks moving at surprising supersonic speeds as well as the expanding tangle of defects deep inside the cube that can harden a tough, flexible material to the point of brittle fracture. "Handling the data was a research project in itself," said Tomas Diaz de la Rubia, LLNL physicist. "Visualizing and navigating within huge datasets such as these is a milestone of the Accelerated Strategic Computing Initiative (ASCI ASCI American Society for Clinical Investigation. ) project that we have now achieved." Details and results of the computer simulation experiments are published in two technical papers and the cover illustration of Tuesday's (April 30) online edition of the prestigious Proceedings of the National Academy of Sciences The Proceedings of the National Academy of Sciences of the United States of America, usually referred to as PNAS, is the official journal of the United States National Academy of Sciences. . (Stunning videos and stills of the computer simulation can be seen at: http://www.research.ibm.com/resources/news/20020429_fracture_ simulation.shtml) (Due to the length of this URL URL in full Uniform Resource Locator Address of a resource on the Internet. The resource can be any type of file stored on a server, such as a Web page, a text file, a graphics file, or an application program. , it may be necessary to copy and paste To copy files from one location to another or to copy text and images from one document to another. All modern operating systems and applications have a copy and paste capability that is typically selected from an Edit menu. See cut and paste and Win Copy between windows. this hyperlink into your Internet browser's URL address field.) Technical details The first paper describes a 20-million-atom simulation that shows how brittle-fracture cracks can travel far faster than theory had previously predicted. This result is expected to be important in helping scientists understand a wide range of fractures -- from shallow earthquakes to the sudden failure of fiber-reinforced composite materials, such as those used in airplanes. The second paper recounts a 1-billion-atom simulation of "work hardening" -- the process by which deformation strengthens a material but can embrittle em·brit·tle tr. & intr.v. em·brit·tled, em·brit·tling, em·brit·tles To make or become brittle. em·brit it if overdone. Bending a paper clip back and forth is an example of work hardening: the metal is initially rather flexible, but it soon stiffens and breaks where it was repeatedly stressed. Work hardening also strengthens materials during forging, an important manufacturing technique used to make products as diverse as critical auto parts and golf clubs. In each of the simulations, which required up to 10 days of around-the-clock computations, the supercomputer calculated the forces between each of the atoms and its neighbors and their positions as the edges of a notched cube or atoms were pulled apart. In the brittle fracture simulation, a crack formed at the notch and traveled rapidly through the material as stress concentrated at the crack tip and ripped apart the chemical bonds that held nearby atoms together. The IBM/LLNL scientists found that when the material is given the property of becoming stiffer, not weaker, as it is stressed --as occurs with certain polymers and rubbers -- the crack tip can shoot through the material at supersonic speeds (that is, faster than the speed of sound in that material). Such behavior was long thought to be impossible. But in recent years, supersonic crack speeds have been observed directly, or suspected, in both laboratory experiments and two devastating 1999 earthquakes in Turkey. The IBM/LLNL simulation gives a sound theoretical footing to such claims and will result in improved tools to understand and predict the behaviors of earthquakes and to design new materials that can resist brittle fracture. In the work hardening computation, the simulated material was made to be tough, not brittle. That meant that the atoms would initially respond to stress by sliding past each other rather than simply breaking apart. The offset atoms create lines of misalignment mis·a·ligned adj. Incorrectly aligned. mis  a·lign ment n. in the periodic structure of the material that are called dislocations. In a soft metal under stress, such dislocations simply pass through the material as deformation occurs. But in a stronger or more complex material, various dislocations collide, which halts further atomic motion at each intersection. As deformation continues, these pinned dislocations accumulate, initially increasing the strength of the material because it can resist a greater force. But if the stress continues, the density of pinned dislocations can become so great that the material turns brittle and breaks. In addition to Abraham and Diaz de la Rubia, co-authors were Robert Walkup walk·up also walk-up n. 1. An apartment house or office building with no elevator. 2. An apartment or office in a building with no elevator. of IBM's T.J. Watson Research Center, Yorktown Height, N.Y.; New Yor; Huajian Gao, a visiting scientist at IBM-Almaden now at the Max Planck Institute for Metals Research The Max Planck Institute for Metals Research (German: Max-Planck-Institut für Metallforschung ) is a research institute of the Max Planck Society located in Stuttgart. The institute was founded 1921 as Kaiser Wilhelm Institute for Metal Research in Berlin and closed 1932. in Stuttgart, Germany; and Mark Duchaineau and Mark Seager of LLNL. Over the past three decades, Abraham has been a pioneer in using the most powerful computers available to calculate and predict materials properties. In 1985, he was able to model 200,000 atoms -- a flat square having only 450 atoms on a side. In July 1994, he published a million-atom simulation, including the first-ever World Wide Web video linked from a scientific paper. ("Instability Dynamics of Fracture: A Computer Simulation" by F. Abraham, D. Brodbeck, R. A. Rafey and W. E. Rudge, Physical Review Letters Physical Review Letters is one of the most prestigious journals in physics.[1] Since 1958, it has been published by the American Physical Society as an outgrowth of The Physical Review. , Vol. 73, No. 2, 11 July 1994, pp. 272-275.) |
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