Sackur–Tetrode equation

The Sackur–Tetrode equation is an expression for the entropy of a monatomic classical ideal gas which incorporates quantum considerations which give a more detailed description of its regime of validity.

The Sackur–Tetrode equation is named for Hugo Martin Tetrode^[1] (1895–1931) and Otto Sackur^[2] (1880–1914), who developed it independently as a solution of Boltzmann's gas statistics and entropy equations, at about the same time in 1912.

Formula

The Sackur–Tetrode equation is this:

{\frac {S}{kN}}=\ln \left[{\frac {V}{N}}\left({\frac {4\pi m}{3h^{2}}}{\frac {U}{N}}\right)^{3/2}\right]+{\frac {5}{2}}

where V is the volume of the gas, N is the number of particles in the gas, U is the internal energy of the gas, k is Boltzmann's constant, m is the mass of a gas particle, h is Planck's constant, and ln is the natural logarithm. For a derivation of the Sackur–Tetrode equation, see the Gibbs paradox. For the constraints placed upon the entropy of an ideal gas by thermodynamics alone, see the ideal gas article.

The Sackur–Tetrode equation can also be conveniently expressed in terms of the thermal wavelength $\Lambda$ .

{\frac {S}{kN}}=\ln \left({\frac {V}{N\Lambda ^{3}}}\right)+{\frac {5}{2}}

Note that the assumption was made that the gas is in the classical regime, and is described by Maxwell–Boltzmann statistics (with "correct Boltzmann counting"). From the definition of the thermal wavelength, this means the Sackur–Tetrode equation is only valid for

{\frac {V}{N\Lambda ^{3}}}\gg 1

and in fact, the entropy predicted by the Sackur–Tetrode equation approaches negative infinity as the temperature approaches zero.

Sackur–Tetrode constant

The Sackur–Tetrode constant, written S₀/R, is equal to S/kN evaluated at a temperature of T = 1 kelvin, at standard pressure (100 kPa or 101.325 kPa, to be specified), for one mole of an ideal gas composed of particles of mass equal to one atomic mass unit (m_u = 1.660 539 040(20)×10⁻²⁷ kg). Its 2014 CODATA recommended value is:^[3]

S₀/R = −1.151 7084(14) for p^o = 100 kPa

S₀/R = −1.164 8714(14) for p^o = 101.325 kPa.

Derivation from information theoretic perspective

In addition to using the thermodynamic perspective of entropy, the tools of information theory can be used to provide an information perspective of entropy. The Sackur–Tetrode equation for entropy can be derived in information theoretic terms. The equation can be seen to consist of the sum of four entropies (missing information): due to positional uncertainty, momenta uncertainty, the quantum mechanical uncertainty principle, and the indistinguishability of the particles.^[4]

Including k, the Sackur–Tetrode equation is then given as

{\begin{aligned}{\frac {S}{kN}}&=[\ln V]+\left[{\frac {3}{2}}\ln \left(2\pi emkT\right)\right]+[-3\ln h]+\left[-{\frac {\ln N!}{N}}\right]\\&\approx \ln \left[{\frac {V}{N}}\left({\frac {2\pi mkT}{h^{2}}}\right)^{\frac {3}{2}}\right]+{\frac {5}{2}}\end{aligned}}

The derivation uses the Stirling's approximation, $\ln N!\approx N\ln N-N$ . Strictly speaking, the use of dimensioned arguments to the logarithms is incorrect, however their use is a "shortcut" made for simplicity. If each logarithmic argument were divided by an unspecified standard value expressed in terms of an unspecified standard mass, length and time, these standard values would cancel in the final result, yielding the same conclusion. The individual entropy terms will not be absolute, but will rather depend upon the standards chosen, and will differ with different standards by an additive constant.

References

↑ H. Tetrode (1912) "Die chemische Konstante der Gase und das elementare Wirkungsquantum" (The chemical constant of gases and the elementary quantum of action), Annalen der Physik 38: 434–442. See also: H. Tetrode (1912) "Berichtigung zu meiner Arbeit: "Die chemische Konstante der Gase und das elementare Wirkungsquantum" " (Correction to my work: "The chemical constant of gases and the elementary quantum of action"), Annalen der Physik 39: 255–256.
↑
Sackur published his findings in the following series of papers:
1. O. Sackur (1911) "Die Anwendung der kinetischen Theorie der Gase auf chemische Probleme" (The application of the kinetic theory of gases to chemical problems), Annalen der Physik, 36: 958–980.
2. O. Sackur, "Die Bedeutung des elementaren Wirkungsquantums für die Gastheorie und die Berechnung der chemischen Konstanten" (The significance of the elementary quantum of action to gas theory and the calculation of the chemical constant), Festschrift W. Nernst zu seinem 25jährigen Doktorjubiläum gewidmet von seinen Schülern (Halle an der Saale, Germany: Wilhelm Knapp, 1912), pages 405–423.
3. O. Sackur (1913) "Die universelle Bedeutung des sog. elementaren Wirkungsquantums" (The universal significance of the so-called elementary quantum of action), Annalen der Physik 40: 67–86.
↑ CODATA2014
↑ Ben-Naim, Arieh (2008), A Farewell to Entropy: Statistical Thermodynamics Based on Information, World Scientific, ISBN 978-981-270-706-2, retrieved 2017-12-12 .

Statistical mechanics
Theory	Principle of maximum entropy ergodic theory
Statistical thermodynamics	Ensembles partition functions equations of state thermodynamic potential: U H F G Maxwell relations
Models	Ferromagnetism models Ising Potts Heisenberg percolation Particles with force field depletion force Lennard-Jones potential
Mathematical approaches	Boltzmann equation H-theorem Vlasov equation BBGKY hierarchy stochastic process mean field theory and conformal field theory
Critical phenomena	Phase transition Critical exponents correlation length size scaling
Entropy	Boltzmann Shannon Tsallis Rényi von Neumann
Applications	Statistical field theory elementary particle superfluidity condensed matter physics complex system chaos information theory Boltzmann machine

Sackur–Tetrode equation

Formula

Sackur–Tetrode constant

Derivation from information theoretic perspective

References

Further reading