Beams from $657 million next-generation synchrotron will reveal atomic-scale structure of proteins and materials
China is set to fire up a powerful new x-ray light source that will reveal the atomic-scale structure of proteins and materials. By the end of December, operators expect light to begin to stream into experimental beamlines at the High Energy Photon Source (HEPS) near Beijing, which will become one of just a handful of “fourth-generation” synchrotrons in the world.
HEPS revs electrons up to high energies and bends them around a circular track so the particles emit synchrotron radiation—mostly short-wavelength “hard” x-rays. The intense, laserlike x-rays are siphoned off into 14 beamlines that scientists will use to image materials and biological structures at atomic to nanometer scales and take snapshots of chemical reactions over nanosecond time frames.
“It’s like getting a major new telescope. You can see things that were not observable before,” says Mingda Li, who studies the quantum properties of materials at the Massachusetts Institute of Technology and chairs the users’ executive committee for the Advanced Photon Source (APS), a U.S. Department of Energy synchrotron at Argonne National Laboratory. “This is a very exciting time for the synchrotron community.”
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Archive (archive.today) - Archive was struggling with this at time of posting.
>Beams from $657 million next-generation synchrotron will reveal atomic-scale structure of proteins and materials
>China is set to fire up a powerful new x-ray light source that will reveal the atomic-scale structure of proteins and materials. By the end of December, operators expect light to begin to stream into experimental beamlines at the High Energy Photon Source (HEPS) near Beijing, which will become one of just a handful of “fourth-generation” synchrotrons in the world.
>HEPS revs electrons up to high energies and bends them around a circular track so the particles emit synchrotron radiation—mostly short-wavelength “hard” x-rays. The intense, laserlike x-rays are siphoned off into 14 beamlines that scientists will use to image materials and biological structures at atomic to nanometer scales and take snapshots of chemical reactions over nanosecond time frames.
>“It’s like getting a major new telescope. You can see things that were not observable before,” says Mingda Li, who studies the quantum properties of materials at the Massachusetts Institute of Technology and chairs the users’ executive committee for the Advanced Photon Source (APS), a U.S. Department of Energy synchrotron at Argonne National Laboratory. “This is a very exciting time for the synchrotron community.”
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.
[Archive](https://archive.today/m4yPZ) - Archive was struggling with this at time of posting.