Why does a BEC manifest no atom bunching?

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In summary, Andrew Truscott from the Australian National University said that the wave-particle duality is what allows lasers to emit photons without bunching, and that BEC does not manifest atom bunching.
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James2018
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Hello. I have asked Andrew Truscott of the Australian National University on why do lasers not manifest photon bunching like incoherent light does and BEC not manifest any atom bunching.
Photon+bunching+and+antibunching.jpg


His e-mail reply contains an answer that is a it confusing to me. Can you explain it to me please?

"Bunching is an effect where (at the most fundamental level) two (or more) quantum wavefunctions overlap and interfere. However you only see this interference if the particles are detected within a length scale that we call the correlation length. Within this length - the particles are said to be indistinguishable (i.e. they are coherent) - and so they interfere. The length scale for bunching (read as the length scale the particles are identical (coherent)) is thus a measure of the coherence of the source of particles.
Now as a thermal gas of atoms is cooled, the correlation length grows, and thus so does the length scale for bunching. However once they are cooled beyond the Bose-Einstein condensation critical temperature and achieve an effective T = 0 distribution the idea of individual particles is replaced with the idea that the source is one large wave. In this scenario, the source has an infinite correlation length, so all the particles behave identically and the correlation length across the cloud is uniform and equal to 1. So no bunching signal is observed."
 

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A lot to explain. Are you familiar with the concept of “wave-particle duality”? If not, it’s worth a Wiki. The way it was explained to me, you picture each particle as a wave. These waves are so separate and defined from one another that they behave as descreet particles. However, as the temperatures of the particles is lowered, the wave peaks get lower and the wave length gets longer (the wave sort of “spreads out”). If two waves next to each other spread out enough, the overlap, and this changes their observed behavior. If they overlap enough, their separate wave-like properties cease to be the defining force governing their behavior, and they start acting like one big wave.

Hope that makes at least a little sense. Someone else in the Forums might be able to give you a more mathematical description, if that would help.
 

1. Why does a Bose-Einstein Condensate (BEC) exhibit no atom bunching?

BECs are made up of atoms that have undergone the process of Bose-Einstein condensation, where they lose their individual identities and behave as a single entity. This results in a phenomenon known as quantum coherence, where all the atoms in the BEC share the same quantum state and behave in a synchronized manner. As a result, there is no way to distinguish between individual atoms, hence no atom bunching occurs.

2. How does quantum coherence in a BEC lead to no atom bunching?

In a BEC, all the atoms are in the same quantum state, meaning they have the same position, momentum, and energy. This results in a phenomenon known as superfluidity, where the atoms can flow without any resistance. As a result, there is no way for the atoms to bunch together, as they all have the same velocity and cannot overtake or collide with each other.

3. Is there any relationship between the lack of atom bunching in a BEC and the Heisenberg Uncertainty Principle?

Yes, the Heisenberg Uncertainty Principle states that it is impossible to know the exact position and momentum of a particle simultaneously. In a BEC, all the atoms are in the same quantum state, meaning they have the same position and momentum. This results in a zero uncertainty in both position and momentum, making it impossible for the atoms to bunch together.

4. Can a BEC ever exhibit atom bunching under certain conditions?

In theory, it is possible for a BEC to exhibit atom bunching if there is some external force or disturbance that breaks the quantum coherence. For example, if a strong magnetic field is applied to a BEC, it can cause the atoms to bunch together due to the change in their quantum state.

5. How does the phenomenon of no atom bunching in a BEC have practical applications?

The lack of atom bunching in a BEC is a result of quantum coherence, which is a fundamental property of quantum mechanics. This phenomenon has practical applications in quantum computing, where the synchronization of particles is crucial for performing complex calculations. It also has potential uses in precision measurement and quantum sensors.

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