What kind of bosons can have Bose-Einstein Condensation?

In summary, according to the speaker, some bosons (photons, phonons) can exhibit Bose-Einstein condensation while others cannot. This is due to the difference in how the system is described: in the first description, the system is always quantized around an equilibrium position, while in the second description, the system is always quantized around the center of an octahedron. The speaker also mentions that phonons have BEC regardless of how the system is described.
  • #1
paradoxwst
2
0
I notice that some bosons can exhibit Bose-Einstein condensation while others cannot (photons, phonons). Is it true that the bosons can have BEC only when the total number of particles is conserved? In this case, the chemical potential approaches zero at [tex]T_c[/tex], and particles begin to cluster (significantly) in the ground state.

Btw, is the total number of phonons conserved in a system? If it is not, for photons and phonons, [tex]\mu=0[/tex] as particles are not conserved. Thus, no BEC?

What distinguishes between photons and some other bosons such that the total number of particles can be conserved or not?
 
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  • #2
Well, for phonons that depends also somewhat on definition. Consider as an example some ferroelectric material like Sr Ti O_3. At elevated temperatures, the Ti atom sits on the mean in the center of an octahedron defined by the oxygen atoms. At lower temperatures the system changes from cubic symmetry to some lower symmetry and the Ti atoms are on the mean not in the center of gravity of the oxygen atoms. You may describe the situation in two different ways: In the first description, you quantize the motion always around the corresponding equilibrium position. It is clear that at lower and lower temperatures the number of phonons decreases and there is no BEC.
In the second point of view you always quantize the motion around the center of the octahedron. Then, the expectation value of the phonon field phi does not vanish in the ground state of low symmetry, <0|phi|0> neq 0, and you could describe this as a BEC of the phonons.
 
  • #3
DrDu said:
You may describe the situation in two different ways: In the first description, you quantize the motion always around the corresponding equilibrium position. It is clear that at lower and lower temperatures the number of phonons decreases and there is no BEC.
In the second point of view you always quantize the motion around the center of the octahedron. Then, the expectation value of the phonon field phi does not vanish in the ground state of low symmetry, <0|phi|0> neq 0, and you could describe this as a BEC of the phonons.

So it means whether there is phonon BEC depends on how you quantize the system? But does it have any physical implications whether there is BEC or not? Is the ambiguity a particular trait of phonons (quasiparticles)? Rubidium atoms have BEC regardless of how you describe it right?
 

1. What are bosons?

Bosons are a type of subatomic particle that have integer spin and follow Bose-Einstein statistics. They are one of the two fundamental categories of particles, with the other being fermions.

2. What is Bose-Einstein condensation?

Bose-Einstein condensation is a phenomenon that occurs when a large number of bosons are cooled to a very low temperature, causing them to all occupy the same quantum state. This results in a macroscopic quantum state with unique properties, such as superfluidity and coherence.

3. Which bosons can have Bose-Einstein condensation?

Any type of boson can potentially undergo Bose-Einstein condensation, as long as they are cooled to a low enough temperature. This includes particles like photons, mesons, and even composite particles like helium-4 atoms.

4. What are the conditions for Bose-Einstein condensation to occur?

The main condition for Bose-Einstein condensation to occur is that the particles must have integer spin. Additionally, they must be cooled to a temperature close to absolute zero, typically below 2.17 Kelvin.

5. What are the practical applications of Bose-Einstein condensation?

Bose-Einstein condensation has a wide range of potential applications, including in quantum computing, superconductivity, and precision measurements. It also allows for the study of fundamental quantum phenomena on a macroscopic scale.

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