Published November 17, 2010
Scientists working on the big bang machine in Geneva have done the seemingly impossible: create, capture and release antimatter.
The development could help researchers devise laboratory experiments to learn more about this strange substance, which mostly disappeared from the universe shortly after the Big Bang around 14 billion years ago.
In a new study, physicists at the European Organization for Nuclear Research (CERN) in Geneva were able to create 38 antihydrogen atoms and preserve each for more than one-tenth of a second. The project was part of the ALPHA (short for Antihydrogen Laser PHysics Apparatus) experiment, an international collaboration that includes physicists from the University of California, Berkeley and Lawrence Berkeley National Laboratory (LBNL).
The antihydrogen atoms are composed of a positron (an antimatter electron) orbiting an antiproton nucleus.
"We are getting close to the point at which we can do some classes of experiments on the properties of antihydrogen," said Joel Fajans, a University of California, Berkeley professor of physics, and LBNL faculty scientist. "Since no one has been able to make these types of measurements on antimatter atoms at all, it's a good start."
Antimatter, first predicted by physicist Paul Dirac in 1931, has the opposite charge of normal matter and annihilates completely in a flash of energy upon interaction with normal matter. Antimatter is produced during high-energy particle interactions on Earth and in some decays of radioactive elements.
In 1955, University of California, Berkeley physicists Emilio Segre and Owen Chamberlain created antiprotons in the Bevatron accelerator at the Lawrence Radiation Laboratory (now called Lawrence Berkeley), confirming their existence and earning the scientists the 1959 Nobel Prize in physics.
To create antihydrogen and keep it from immediately annihilating, the ALPHA team cooled antiprotons and compressed them into a matchstick-size cloud. Then the researchers nudged this cloud of cold, compressed antiprotons so it overlapped with a like-size positron cloud, where the two particles mated to form antihydrogen.
All this happened inside a magnetic bottle that traps the antihydrogen atoms. The magnetic trap is a specially configured magnetic field that uses an unusual and expensive superconducting magnet to prevent the antimatter particles from running into the edges of the bottle -- which is made of normal matter and would annihilate with the antimatter on contact.
"For the moment, we keep antihydrogen atoms around for at least 172 milliseconds -- about a sixth of a second -- long enough to make sure we have trapped them," said Jonathan Wurtele, a University of California, Berkeley professor of physics and LBNL faculty scientist.
The team's results will be published online Nov. 17 in the journal Nature.
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