What happens to the particles in Bose Einstein condensate?

What happens to the particles in Bose Einstein condensate?

Bose-Einstein condensate (BEC), a state of matter in which separate atoms or subatomic particles, cooled to near absolute zero (0 K, − 273.15 °C, or − 459.67 °F; K = kelvin), coalesce into a single quantum mechanical entity—that is, one that can be described by a wave function—on a near-macroscopic scale.

How does Bose Einstein condensate act?

A Bose-Einstein condensate is a group of atoms cooled to within a hair of absolute zero. At that point, the atoms begin to clump together, and enter the same energy states. They become identical, from a physical point of view, and the whole group starts behaving as though it were a single atom.

How is light slowed?

Scientists have long known that the speed of light can be slowed slightly as it travels through materials such as water or glass. However, it has generally been thought impossible for particles of light, known as photons, to be slowed as they travel through free space, unimpeded by interactions with any materials.

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What is BEC (Bose-Einstein condensation)?

Bose-Einstein condensation (BEC) is a fascinating phenomenon, one that results from quantum statistics for identical particles with an integer spin, called bosons. Sometimes referred to as the fifth state of matter, it was originally predicted in 1924 by Albert Einstein and Satyendra Nath Bose.

How long does a Bose Einstein condensate last?

The result was a Bose-Einstein condensate of about 2,000 rubidium atoms that lasted for 15 to 20 seconds. New machines can now make condensates of much greater numbers of atoms that last up to three minutes.

What is the difference between the Bose-Einstein and Jin-DeMarco experiments?

While the Bose-Einstein experiments used one class of quantum particles known as bosons, Jin and DeMarco cooled atoms that are fermions, the other class of quantum particles found in nature. This was important to physicists because the basic building blocks of matter—electrons, protons and neutrons — are all fermions.

Did we predict this B-E condensate in our model?

“We did not predict this B-E condensate in our model. This is an absolutely new observation,” said Alexander “Sasha” Balatsky. In a recently published open-access paper in the journal Nature Scientific Reports, scientists reported the observation of a room-temperature condensate of optical phonons, called a Bose-Einstein (B-E) condensate.

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