 |
 |
 |
 |
 |
 |
 |
 |
 |
 |
Opposites Interfere
New York NY (SPX) Jul 27, 2007 In a classic physics experiment, photons (light particles), electrons, or any other quantum particles are fired, one at a time, at a sheet with two slits cut in it that sits in front of a recording plate. For photons, a photographic plate reveals an oscillating pattern (bands of light and dark) - a sign that each particle, behaving like a wave, has somehow passed through both slits simultaneously and interfered, canceling the light in some places and enhancing it in others. If single quantum particles can exist in two places at once, and interfere with themselves in predictable patterns, what happens when there are two quantum particles? Can they interfere with each other? Prof. Mordehai Heiblum of the Weizmann Institute's Condensed Matter Physics Department and his research team have been experimenting with electrons fired across special semiconductor devices. Quantum mechanics predicts that two electrons can indeed cause the same sort of interference as that of a single electron - on one condition: that the two are identical to the point of being indistinguishable. Heiblum and his team showed that, because of such interference, these two particles are entangled - the actions of one are inextricably tied to the actions of the other - even though they come from completely different sources and never interact with each other. The team's findings recently appeared in the journal Nature. Dr. Izhar Neder and Nissim Ofek, together with Drs. Yunchul Chung, Diana Mahalu, and Vladimir Umansky, fired such identical electron pairs from opposite sides of their device, toward detectors that were placed two to a side of the device. In other words, each pair of detectors could detect the two particles arriving in one of two ways: particle 1 in detector 1 and particle 2 in detector 2, or, alternatively, particle 2 in detector 1 and particle 1 in detector 2. Since these two "choices" are indistinguishable, the choices interfere with each other in the same way as the two possible paths of a single quantum particle interfere. The scientists then investigated how the choice of one particle affected the pathway taken by the other, and found strong correlations between them. These correlations could be affected by changing, for example, the length of the path taken by one particle. This is the first time an oscillating interference pattern between two identical particles has been observed, proving, once again, the success of quantum theory. Prof. Mordehai Heiblum's research is supported by the Joseph H. and Belle R. Braun Center for Submicron Research; the Wolfson Family Charitable Trust; Hermann Mayer and Dan Mayer; and Mr. Roberto Kaminitz, Sao Paulo, Brazil. Prof. Heiblum is the incumbent of the Alex and Ida Sussman Professorial Chair in Submicron Electronics. Related Links Weizmann Institute of Science Understanding Time and Space
Researchers Produce Firsts With Bursts Of Light
Upton NY (SPX) Jul 27, 2007Researchers at the U.S. Department of Energy's Brookhaven National Laboratory have generated extremely short pulses of light that are the strongest of their type ever produced and could prove invaluable in probing the ultra-fast motion of atoms and electrons. The scientists also made the first observations of a phenomenon called cross-phase modulation with this high-intensity light - a characteristic that could be used in numerous new light source technologies. |
|
|
| The content herein, unless otherwise known to be public domain, are Copyright Space.TV Corporation. AFP and UPI Wire Stories are copyright Agence France-Presse and United Press International. ESA Portal Reports are copyright European Space Agency. All NASA sourced material is public domain. Additional copyrights may apply in whole or part to other bona fide parties. Advertising does not imply endorsement, agreement or approval of any opinions, statements or information provided by Space.TV Corp on any Web page published or hosted by Space.TV Corp. Privacy Statement |
