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β. Condensed bosons

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As μ gets closer to zero, the population N0 of the ground state becomes:

(63)

This population diverges in the limit μ = 0 and, when |μ| gets small enough, it can become arbitrarily large. It can, for example, become proportional5 to the volume , in which case it adds a finite contribution to the particle numerical density (particle number per unit volume) as .

This particularity is limited to the ground state, which, in this case, plays a very different role than the other levels. Let us show, for example, that the first excited state population does not yield a similar effect. Assuming the system to be contained in a cubic box6 of edge length L, the population of the first excited energy level e1 ~ π2ħ2/(2mL2 ) can be written as:

(64)

(we assume the box to be large enough so that L ≫ λT, which means βe1 ≪ 1); this population can therefore be proportional only to the square of L, i.e. to the volume to the power 2/3. It shows that this first excited level cannot make a contribution to the particle density in the limit L → ∞; the same is true for all the other excited levels whose contributions are even smaller. The only arbitrary contribution to the density comes from the ground state.

This arbitrarily large value as μ → 0 obviously does not appear in relation (59), which predicts that the density is always less than a finite value as shown by (62). This is not surprising: as the population varies radically from the first energy level to the next, we can no longer compute the average particle number by replacing in (55) the discrete summation by an integral and a more precise calculation is necessary. Actually, only the ground state population must be treated separately, and the summation over all the excited states (of which none contributes to the density divergence) can still be replaced by an integral as before. Consequently, to get the total population of the physical system we simply add the integral on the right-hand side of (57) to the contribution N0 of the ground level:

(65)

where N0 is defined in (63).

As μ → 0, the total population of all the excited levels (others than the ground level) remains practically constant and equal to its upper limit (62); only the ground state has a continuously increasing population N0, which becomes comparable to the total population of all the excited states when the right-hand sides of (63) and (62) are of the same order of magnitude:

(66)

(μ being of course always negative). When this condition is satisfied, a significant fraction of the particles accumulates in the individual ground level, which is said to have a “macroscopic population” (proportional to the volume). We can even encounter situations where the majority of the particles all occupy the same quantum state. This phenomenon is called “Bose-Einstein condensation” (it was predicted by Einstein in 1935, following Bose’s studies of quantum statistics applicable to photons). It occurs when the total density ntot reaches the maximum predicted by formula (62), that is:

(67)

This condition means that the average distance between particles is of the order of the thermal wavelength λT.

Initially, Bose-Einstein condensation was considered to be a mathematical curiosity rather than an important physical phenomenon. Later on, people realized that it played an important role in superfluid liquid Helium 4, although this was a system with constantly interacting particles, hence far from an ideal gas. For a dilute gas, Bose-Einstein condensation was observed for the first time in 1995, and in a great number of later experiments.

Quantum Mechanics, Volume 3

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