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March 24, 2004
MONTREAL, CANADA - By bombarding very thin slices of several copper/oxygen compounds, called cuprates, with very bright, short-lived pulses of light, Ivan Bozovic, a physicist at the U.S. Department of Energy's Brookhaven National Laboratory, and his collaborators have discovered an unusual property of the materials: After absorbing the light energy, they emit it as long-lived sound waves, as opposed to heat energy. This result may open up a new field of study on cuprates - materials already used in wireless communications and under investigation for other applications in the electronics industry.
As the light pulses strike each film, illuminating an area only about a thousandth of a millimeter across, they transfer their energy to the film's atoms. In response, the atoms vibrate, and tiny sound wave "packets," called phonons, spread through the sample. Bozovic observes that, mysteriously, these emitted sound waves do not die out quickly, as they do with other materials. Instead, the atoms oscillate many times before dissipating the absorbed energy. "This is very unusual, as it seems that the atoms find it hard to convert these oscillations into ordinary thermal energy (heat)," said Bozovic.
Through further studies, Bozovic hopes to learn more about this phenomenon, the first step toward finding possible applications for it. For example, this work could contribute to the development of a phaser, a laser-like device that emits phonons instead of light. "Much more research needs to be done," Bozovic said. "We don't know yet how this property might be useful. However, I have little doubt that the phaser would be a very useful scientific tool for a broad new class of experiments," Bozovic said.
Bozovic will present his work at 1:03 p.m. on Friday, March 26, in room 517A, during the "Excitation in Strongly Correlated Materials II" session. This research is funded by the Air Force Office of Scientific Research, the National Science Foundation, and a Laboratory Directed Research and Development grant from the U.S. Department of Energy's Los Alamos National Laboratory, where part of the work was performed.
2004-118 | Media & Communications Office