Law of corresponding states: Difference between revisions

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by Noro and  Frenkel
by Noro and  Frenkel
<ref>[http://dx.doi.org/10.1063/1.1288684 Massimo G. Noro and Daan Frenkel "Extended corresponding-states behavior for particles with variable range attractions", Journal of Chemical Physics '''113''' 2941-2944 (2000)]</ref>.
<ref>[http://dx.doi.org/10.1063/1.1288684 Massimo G. Noro and Daan Frenkel "Extended corresponding-states behavior for particles with variable range attractions", Journal of Chemical Physics '''113''' 2941-2944 (2000)]</ref>.
==See also==
*[[Zeno line]]
==References==
==References==
<references/>
<references/>
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*[http://dx.doi.org/10.1063/1.3072156 Patrick Grosfils and James F. Lutsko "Dependence of the liquid-vapor surface tension on the range of interaction: A test of the law of corresponding states", Journal of Chemical Physics '''130''' 054703 (2009)]
*[http://dx.doi.org/10.1063/1.3072156 Patrick Grosfils and James F. Lutsko "Dependence of the liquid-vapor surface tension on the range of interaction: A test of the law of corresponding states", Journal of Chemical Physics '''130''' 054703 (2009)]
*Hong Wei Xiang "The Corresponding-States Principle and its Practice", Elsevier Science (2005) ISBN 0-444-52062-7
*Hong Wei Xiang "The Corresponding-States Principle and its Practice", Elsevier Science (2005) ISBN 0-444-52062-7
*[http://dx.doi.org/10.1063/1.3496468  L. A. Bulavin  and V. L. Kulinskii "Generalized principle of corresponding states and the scale invariant mean-field approach", Journal of Chemical Physics ''''133''' 134101 (2010)]
[[category: equations of state]]
[[category: equations of state]]

Revision as of 13:17, 6 October 2010

The law of corresponding states is an empirical law which encapsulates the finding that the equations of state for many real gases are remarkably similar when they are expressed in terms of reduced temperatures (), pressures, () and volumes (), where the subscript represents the value of the property at the critical point. This law was first described by Johannes Diderik van der Waals in his 1873 thesis, and forms the subject of a paper by him in 1913 [1]

Assumptions

Pitzer [2] produced a list of assumptions in order for the law of corresponding states to apply. This list was later modified by Guggenheim [3]. These are:

  1. There is negligible difference between Fermi–Dirac statistics and Bose–Einstein statistics for the system (i.e. the system behaves classically).
  2. The effect of quantisation of the translational degrees of freedom is negligible (i.e. the system behaves classically).
  3. The molecules are spherically symmetrical, either actually or by virtue of rapid and free rotation.
  4. The intramolecular degrees of freedom are assumed to be completely independent of the volume per molecule.
  5. The potential energy will be taken as a function only of the various intermolecular distances.
  6. The potential energy for a pair of molecules can be written as where is the intermolecular distance, and and are characteristic constants, and is a universal function.

Examples

For argon, krypton, nitrogen, oxygen, carbon dioxide and methane one has [3]

(for pressure measured in atmospheres, and volume in cm3mole-1)

For neon, argon, and oxygen one has [3]

where is the Boyle temperature.

For neon, argon, krypton,and xenon one has [3]

where is the triple point.

Acentric factor

The acentric factor [4] is defined in terms of the vapour pressure at . It has been shown that a number of substances have the behavior if they share the same acentric factor.

Colloids

The law of corresponding states has been extended to suspensions of spherical colloids that interact via a pair potential by Noro and Frenkel [5].

See also

References

Related material