Virial expansion

The classical virial expansion expresses the pressure of a many-particle system in equilibrium as a power series in the number density. The virial expansion, introduced in 1901 by Heike Kamerlingh Onnes, is a generalization of the ideal gas law. He wrote that for a gas containing atoms or molecules,

where is the pressure, is the Boltzmann constant, is the absolute temperature, and is the number density of the gas. Note that for a gas containing a fraction of (Avogadro's number) molecules, truncation of the virial expansion after the first term leads to , which is the ideal gas law.

Writing , the virial expansion can be written as

.

The virial coefficients are characteristic of the interactions between the particles in the system and in general depend on the temperature . Virial expansion can also be applied to aqueous ionic solutions, as shown by Harold Friedman.

Comparison with Van der Waals equation

The Van der Waals equation can be used to derive the approximation with the Van der Waals constants a and b.

And when then , see Boyle temperature.

According to Van der Waals constants (data page) the constants for hydrogen gas are for example a = 0.2476 L2bar/mol2 and b = 0.02661 L/mol and therefore the estimation of the Boyle temperature for hydrogen is . (The real value for hydrogen is 110 K.[2] In nitrogen the difference is bigger.)

See also

Notes and references

  1. Chang, Raymond (2014). Physical Chemistry for the Chemical Sciences. University Science Books. p. 14. ISBN 978-1-891389-69-6.
  2. Real Gases and the Virial Equation Table 1.2
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