Bose gas

Condensed matter physics

Phases · Phase transition · QCP
States of matter Solid · Liquid · Gas · Plasma · Bose–Einstein condensate · Bose gas · Fermionic condensate · Fermi gas · Fermi liquid · Supersolid · Superfluidity · Luttinger liquid
Phase phenomena Order parameter · Phase transition · QCP
Electronic phases Electronic band structure · Insulator · Mott insulator · Semiconductor · Semimetal · Conductor · Superconductor · Thermoelectric · Piezoelectric · Ferroelectric · Topological insulator · Spin gapless semiconductor
Electronic phenomena Quantum Hall effect · Spin Hall effect · Kondo effect
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Quasiparticles Phonon · Exciton · Plasmon Polariton · Polaron · Magnon
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Scientists Van der Waals · Onnes · von Laue · Bragg · Debye · Bloch · Onsager · Mott · Peierls · Landau · Luttinger · Anderson · Van Vleck · Mott · Hubbard · Shockley · Bardeen · Cooper · Schrieffer · Josephson · Louis Néel · Esaki · Giaever · Kohn · Kadanoff · Fisher · Wilson · von Klitzing · Binnig · Rohrer · Bednorz · Müller · Laughlin · Störmer · Tsui · Abrikosov · Ginzburg · Leggett

An ideal Bose gas is a quantum-mechanical version of a classical ideal gas. It is composed of bosons, which have an integer value of spin, and obey Bose–Einstein statistics. The statistical mechanics of bosons were developed by Satyendra Nath Bose for photons, and extended to massive particles by Albert Einstein who realized that an ideal gas of bosons would form a condensate at a low enough temperature, unlike a classical ideal gas. This condensate is known as a Bose–Einstein condensate.

Thomas–Fermi approximation

Inclusion of the ground state

The total number of particles is found from the grand potential by

N=-z{\frac {\partial \Omega }{\partial z}}\approx {\frac {{\textrm {Li}}_{\alpha }(z)}{(\beta E_{c})^{\alpha }}}

The polylogarithm term must remain real and positive, and the maximum value it can possibly have is at z=1 where it is equal to ζ(α) where ζ is the Riemann zeta function. For a fixed N , the largest possible value that β can have is a critical value β_c where

N={\frac {\zeta (\alpha )}{(\beta _{c}E_{c})^{\alpha }}}

This corresponds to a critical temperature T_c=1/kβ_c below which the Thomas–Fermi approximation breaks down. The above equation can be solved for the critical temperature:

T_{c}=\left({\frac {N}{\zeta (\alpha )}}\right)^{{1/\alpha }}{\frac {E_{c}}{k}}

For example, for $\alpha =3/2$ and using the above noted value of $E_{c}$ yields

T_{c}=\left({\frac {N}{Vf\zeta (3/2)}}\right)^{{2/3}}{\frac {h^{2}}{2\pi mk}}

Again, we are presently unable to calculate results below the critical temperature, because the particle numbers using the above equation become negative. The problem here is that the Thomas–Fermi approximation has set the degeneracy of the ground state to zero, which is wrong. There is no ground state to accept the condensate and so the equation breaks down. It turns out, however, that the above equation gives a rather accurate estimate of the number of particles in the excited states, and it is not a bad approximation to simply "tack on" a ground state term:

N=N_{0}+{\frac {{\textrm {Li}}_{\alpha }(z)}{(\beta E_{c})^{\alpha }}}

where N₀ is the number of particles in the ground state condensate:

N_{0}={\frac {g_{0}\,z}{1-z}}

Figure 1: Various Bose gas parameters as a function of normalized temperature τ. The value of α is 3/2. Solid lines are for N=10,000, dotted lines are for N=1000. Black lines are the fraction of excited particles, blue are the fraction of condensed particles. The negative of the chemical potential μ is shown in red, and green lines are the values of z. It has been assumed that k =ε_c=1.

This equation can now be solved down to absolute zero in temperature. Figure 1 shows the results of the solution to this equation for α=3/2, with k=ε_c=1 which corresponds to a gas of bosons in a box. The solid black line is the fraction of excited states 1-N₀/N for N =10,000 and the dotted black line is the solution for N =1000. The blue lines are the fraction of condensed particles N₀/N The red lines plot values of the negative of the chemical potential μ and the green lines plot the corresponding values of z . The horizontal axis is the normalized temperature τ defined by

\tau ={\frac {T}{T_{c}}}

It can be seen that each of these parameters become linear in τ^α in the limit of low temperature and, except for the chemical potential, linear in 1/τ^α in the limit of high temperature. As the number of particles increases, the condensed and excited fractions tend towards a discontinuity at the critical temperature.

The equation for the number of particles can be written in terms of the normalized temperature as:

N={\frac {g_{0}\,z}{1-z}}+N~{\frac {{\textrm {Li}}_{\alpha }(z)}{\zeta (\alpha )}}~\tau ^{\alpha }

For a given N and τ, this equation can be solved for τ^α and then a series solution for z can be found by the method of inversion of series, either in powers of τ^α or as an asymptotic expansion in inverse powers of τ^α. From these expansions, we can find the behavior of the gas near T =0 and in the Maxwell–Boltzmann as T approaches infinity. In particular, we are interested in the limit as N approaches infinity, which can be easily determined from these expansions.

Thermodynamics

Adding the ground state to the equation for the particle number corresponds to adding the equivalent ground state term to the grand potential:

\Omega =g_{0}\ln(1-z)-{\frac {{\textrm {Li}}_{{\alpha +1}}(z)}{\left(\beta E_{c}\right)^{\alpha }}}

All thermodynamic properties may now be computed from the grand potential. The following table lists various thermodynamic quantities calculated in the limit of low temperature and high temperature, and in the limit of infinite particle number. An equal sign (=) indicates an exact result, while an approximation symbol indicates that only the first few terms of a series in $\tau ^{\alpha }$ is shown.

Quantity	General	$T\ll T_{c}\,$	$T\gg T_{c}\,$
z		$\approx {\frac {\zeta (\alpha )}{\tau ^{\alpha }}}-{\frac {\zeta ^{2}(\alpha )}{2^{\alpha }\tau ^{{2\alpha }}}}$	$=1\,$
Vapor fraction $1-{\frac {N_{0}}{N}}\,$	$={\frac {{\textrm {Li}}_{{\alpha }}(z)}{\zeta (\alpha )}}\,\tau ^{\alpha }$	$=\tau ^{\alpha }\,$	$=1\,$
Equation of state ${\frac {PV\beta }{N}}=-{\frac {\Omega }{N}}\,$	$={\frac {{\textrm {Li}}_{{\alpha \!+\!1}}(z)}{\zeta (\alpha )}}\,\tau ^{\alpha }$	$={\frac {\zeta (\alpha \!+\!1)}{\zeta (\alpha )}}\,\tau ^{\alpha }$	$\approx 1-{\frac {\zeta (\alpha )}{2^{{\alpha \!+\!1}}\tau ^{\alpha }}}$
Gibbs Free Energy $G=\ln(z)\,$	$=\ln(z)\,$	$=0\,$	$\approx \ln \left({\frac {\zeta (\alpha )}{\tau ^{\alpha }}}\right)-{\frac {\zeta (\alpha )}{2^{{\alpha }}\tau ^{\alpha }}}$

It is seen that all quantities approach the values for a classical ideal gas in the limit of large temperature. The above values can be used to calculate other thermodynamic quantities. For example, the relationship between internal energy and the product of pressure and volume is the same as that for a classical ideal gas over all temperatures:

U={\frac {\partial \Omega }{\partial \beta }}=\alpha PV

A similar situation holds for the specific heat at constant volume

C_{v}={\frac {\partial U}{\partial T}}=k(\alpha +1)\,U\beta

The entropy is given by:

TS=U+PV-G\,

Note that in the limit of high temperature, we have

TS=(\alpha +1)+\ln \left({\frac {\tau ^{\alpha }}{\zeta (\alpha )}}\right)

which, for α=3/2 is simply a restatement of the Sackur–Tetrode equation. In one dimension bosons with delta interaction behave as fermions, they obey Pauli exclusion principle. In one dimension Bose gas with delta interaction can be solved exactly by Bethe ansatz. The bulk free energy and thermodynamic potentials were calculated by Chen Nin Yang. In one dimensional case correlation functions also were evaluated. The In one dimension Bose gas is equivalent to quantum non-linear Schroedinger equation.

References

Huang, Kerson (1967). Statistical Mechanics. New York: John Wiley and Sons.
Isihara, A. (1971). Statistical Physics. New York: Academic Press.
Landau, L. D.; E. M. Lifshitz (1996). Statistical Physics, 3rd Edition Part 1. Oxford: Butterworth-Heinemann.
Pethick, C. J.; H. Smith (2004). Bose–Einstein Condensation in Dilute Gases. Cambridge: Cambridge University Press.
Yan, Zijun (2000). "General Thermal Wavelength and its Applications" (PDF). Eur. J. Phys. 21 (6): 625–631. Bibcode:2000EJPh...21..625Y. doi:10.1088/0143-0807/21/6/314.

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Bose gas

Thomas–Fermi approximation

Inclusion of the ground state

Thermodynamics

See also

References