A New Form of Matter
"To see something which nobody else has seen before is thrilling and deeply satisfying. Those are the moments when you want to be a scientist," says Wolfgang Ketterle, a physicist at MIT and one of the first scientists to create a new kind of matter called Bose-Einstein condensates.
Right: Nobel prizing-winning scientists used lasers and magnetic fields to create a new form of matter. [learn more] Image © 2002 The Nobel Foundation.
Bose-Einstein condensates ("BECs" for short) aren't like the solids, liquids and gases that we learned about in school. They are not vaporous, not hard, not fluid. Indeed, there are no ordinary words to describe them because they come from another world -- the world of quantum mechanics.
Although quantum rules are counter-intuitive, they underlie the macroscopic reality we experience day-to-day. Bose-Einstein condensates are curious objects that bridge the gap between those two realms. They obey the laws of the small even as they intrude on the big.
Below: BECs form when the atoms in a gas undergo a transition from behaving like the "flying billiard balls" of classical physics to behaving as one giant matter-wave. Image courtesy MIT.
Says Ketterle: "Pictures of BECs can be regarded as photographs of wave functions" -- that is, solutions to Schrodinger's equation.
Working independently in 1995, Eric Cornell (National Institute of Standards & Technology) and Carl Wieman (University of Colorado) also created BECs; theirs were made of super-cold rubidium atoms. Cornell and Wieman shared the 2001 Nobel Prize with Ketterle "for the achievement of Bose-Einstein condensation in dilute gases of alkali atoms, and for early fundamental studies of the properties of the condensates."
Bose-Einstein condensates were predicted by Indian physicist Satyendra Nath Bose and Albert Einstein in the 1920's when quantum mechanics was still new. Einstein wondered if BECs were too strange to be real even though he himself had thought of them.
Now we know Bose-Einstein condensates are real. And Einstein was right: they are strange.
Above: A picture of overlapping Bose-Einstein condensates. These shadows reveal an "interference pattern" -- a tell-tale sign of wave behavior. Image courtesy MIT.
"That means ... we have the remarkable effect that an atom (in one BEC) plus an atom (in another BEC) gives no atom. It's destructive interference," says Ketterle. "Of course we didn't destroy matter, it just appeared somewhere else in the pattern, so the total number of atoms is conserved."
Right: MIT's Wolfgang Ketterle, 2001 Nobel laureate.
One of the most extraordinary aspects of Bose-Einstein condensates is that they are quantum creatures big enough to see. And there lies much of their promise. Many of today's cutting-edge technologies -- smaller, faster computer chips, micro-electro-mechanical systems (MEMS) and quantum computers -- lie in the twilight zone between the quantum world and the macroscopic world. Scientists hope that studying BECs will advance those technologies and create others.
Ketterle is already experimenting with one: a pulsed atom-laser.
"In an ordinary gas, atoms move around randomly, they flit around in all directions. But in a BEC, all the atoms march lock-step," Ketterle explains. "They are just one single matter-wave propagating in one direction."
Left: Atom-laser pulses produced in Ketterle's lab. The curved shape of the pulses was caused by gravity and forces between the atoms. [more]
"Atom lasers need a vacuum to retain their properties," notes Ketterle. As a result they won't be used in the same way as light-lasers. They won't improve CD players or supermarket scanners, for instance. But atom-lasers will doubtless find uses of their own -- "like better atomic clocks [which will improve spacecraft navigation -- a boon to NASA], atomic optics or very fine lithography," says Ketterle.
Who knows where BECs will lead? After all, humans evolved on this planet with solids, liquids and gases all around, and we're still figuring out innovative uses for them. With Bose-Einstein condensates ... we're just getting started.
Editor's Note: Ketterle's ongoing research is supported in part by NASA along with other agencies.more information
A New Form of Matter -- an on-line lecture by Ketterle introducing and explaining Bose-Einstein condensates. (Highly recommended.)
This work was supported in part by NASA's Office of Biological and Physical Research.
The 2001 Nobel Prize in Physics -- awarded to the lead scientists for the two groups who first created Bose-Einstein condensates.
Illustrated presentation about BECs -- from the Nobel e-Museum Web site
Wolfgang Ketterle's Group at MIT -- home page
Questions and Answers about BECs -- from the University of Colorado
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