Redirected from Bose-Einstein's condensation
The effect can be understood in broad outline by considering the Heisenberg Uncertainty Principle which states, roughly, that it is impossible to know both a particle's velocity and a particle's position simultaneously with certainty. When a group of atoms is cooled to a low enough temperature, however, their velocities become very certain; they must be moving very slowly, or stated more technically they must have low quantum energy levels. This causes their positions to "smear out," effectively causing the individual atoms to overlap each other. In a Bose-Einstein condensate, the many overlapping atoms can be considered to be a single super-atom, with all of its constituent atoms sharing a single quantum state.
A Bose-Einstein condensate was not actually created in a lab until June 5, 1995, when Eric Cornell[?] and Carl Wieman used a combination of laser cooling (a technique the invention of which won Steven Chu[?], Claude Cohen-Tannoudji[?], and William D. Phillips[?] the 1997 Nobel Prize for Physics) and magnetic evaporative cooling[?] to cool a cloud of approximately 2000 rubidium atoms to 20 billionths of a degree above absolute zero, the lowest temperature ever achieved at that time. This was cold enough to form a Bose-Einstein condensate. (Cornell, Wieman and Wolfgang Ketterle[?] won the 2001 Nobel Prize in Physics for this achievement.)
Bose-Einstein condensates are extremely fragile. The slightest interaction with the outside world can be enough to warm them past the condensation threshold, causing them to break back down into individual atoms again; it will likely be some time before any practical applications are developed for them. However, several interesting properties have already been observed in experiments. Bose-Einstein condensates have extremely high optical densities, resulting in extremely low measured speed of light with in them; some condensates have slowed beams of light down to mere meters per second, slower than a human can move on a bicycle. A rotating Bose-Einstein condensate could be used as a model black hole, allowing light to enter but not to escape. Condensates could also be used to "freeze" pulses of light, to be released again when the condensate breaks down. Research in this field is still young and ongoing.
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