GROUNDBREAKING MARKS BERKELEY LAB'S LEAP INTO NANO-REVOLUTION

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GROUNDBREAKING MARKS BERKELEY LAB'S LEAP INTO NANO-REVOLUTION
23 July 2006 - DOE/Lawrence Berkeley National Lab

The term "Molecular Foundry" suggests a place where objects are forged and new materials are molded. Like the foundries of the industrial revolution, this new concept, on a nanoscale, promises to revolutionize the way the world works. It began at the Department of Energy's Lawrence Berkeley National Laboratory.

That's when ground was turned for the official beginning of construction on a six-story, $85 million, 94,500-square-foot research building that will be one of the centerpieces of the DOE's Nanoscale Research Program. Berkeley Lab's Molecular Foundry is one of five DOE research centers to be constructed over the next few years.

"This facility will assist scientists in reaching new frontiers in the study of nanoscale research and its practical application," Secretary of Energy Spencer Abraham said. "It represents a beginning of a revolution in science, opening up a broad array of innovation in materials science, biology, medicine, technologies for environmental research and national security.

"Berkeley is blessed with tremendous resources, such as the national supercomputing center, the Advanced Light Source, and the National Center for Electron Microscopy," he added. "All will be instrumental in the revolution in science offered by the Molecular Foundry."

"Nanoscale research will, in many respects, represent the new building blocks for new technologies and applications across the science and industry spectrum," said Berkeley Lab Director Charles Shank. "Understanding the properties of materials on the tiniest scale will have an impact on everything, from medicine to manufacturing."

Nanoscale research enables scientists literally to build novel structures atom by atom. The fundamental properties of materials and systems are established at the nanoscale. Nanomaterials, typically on the scale of billionths of a meter, or 75,000 times smaller than the width of a human hair, offer different chemical and physical properties than the same materials in bulk form, and have the potential to form the basis for new technologies. This especially includes the realm of molecular biology.

Berkeley Lab's Molecular Foundry, actually the research building around which Foundry programs will be developed, will include six facilities available to users from around the world. These include labs and experts devoted to inorganic nanostructures; nanofabrication; organic, polymer/biopolymer synthesis; biological nanostructures; imaging and manipulation; and theory. Its focus will be on the design, synthesis and characterization of both "soft" (biological and polymer) and "hard" (inorganic and microfabricated) substances and the integration of these into complex assemblies.

The SmithGroup of San Francisco designed the structure, which will follow the contours of a hillside site between a materials research building and the microscopy center. Construction will be coordinated by Rudolph and Sletten, Inc. of Foster City. When completed, the Foundry building will house more than 200 scientists and support staff, using state-of-the-art instrumentation for imaging and manipulation.

Berkeley Lab's facility is one of five in the DOE's proposed Nanoscience Research Program; others will be developed at Oak Ridge National Laboratory, Brookhaven National Laboratory, Argonne National Laboratory and Sandia National Laboratories/Los Alamos National Laboratory.

The possibilities to grow out of this and other initiatives dedicated to the field of nanoscience are virtually limitless. Some potential outcomes that have been suggested include:

Carbon nanotubes, sheets of graphite rolled into extremely narrow tubes a few nanometers in diameter, could be the possible building blocks of future electronic devices.

Nanotechnology may one day enable the detection of disease on the cellular level and the targeting of treatment only to tissues where it is needed in a patient's body, potentially alleviating many unpleasant and sometimes harmful side effects.

Nanomanufacturing of parts and materials "from the bottom up", by assembling them on an atom-by-atom basis, may one day be used to reduce waste and pollution in the manufacturing process.

Nanosensors already are being developed to allow fast, reliable, real-time monitoring for everything from chemical attack to environmental leaks.

Woven into a cable, carbon nanotubes could provide electricity transmission lines with substantially improved performance over current power lines.

Certain nanomaterials show promise for use in making more efficient solar cells and the next-generation catalysts and membranes that will be used in hydrogen-powered fuel cells.

U.S. Rep. Mike Honda, D-San Jose, was featured speaker at the groundbreaking ceremony. Honda was cosponsor of the Boehlert-Honda Nanotechnology Act of 2003, which authorizes $3.7 billion over the next three years for nanotechnology research and development programs.

http://www.lbl.gov

About: DOE/Lawrence Berkeley National Lab
Lawrence Berkeley National Laboratory (Berkeley Lab) has been a leader in science and engineering research for more than 70 years. Located on a 200 acre site in the hills above the Berkeley campus of the University of California, overlooking the San Francisco Bay, Berkeley Lab is a US Department of Energy (DOE) National Laboratory managed by the University of California. It has an annual budget of nearly $480 million (FY2002) and employs a staff of about 3,900, including more than a thousand students.

Berkeley Lab conducts unclassified research across a wide range of scientific disciplines with key efforts in fundamental studies of the universe; quantitative biology; nanoscience; new energy systems and environmental solutions; and the use of integrated computing as a tool for discovery. It is organized into 17 scientific divisions and hosts four DOE national user facilities. Details on Berkeley Lab’s divisions and user facilities can be viewed here.

The Lab was founded in 1931 by Ernest Orlando Lawrence, winner of the 1939 Nobel Prize in physics for his invention of the cyclotron, a circular particle accelerator that opened the door to high-energy physics. It was Lawrence’s belief that scientific research is best done through teams of individuals with different fields of expertise, working together. His teamwork concept is a Berkeley Lab legacy that has yielded rich dividends in basic knowledge and applied technology, and a profusion of awards, including nine Nobel Prizes -- five in physics and four in chemistry.

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