Virial equation of state: Difference between revisions

The virial equation of state is used to describe the behavior of diluted gases. It is usually written as an expansion of the compresiblity factor, ${\displaystyle Z}$, in terms of either the density or the pressure. In the first case:

${\displaystyle {\frac {pV}{Nk_{B}T}}=Z=1+\sum _{k=2}^{\infty }B_{k}(T)\rho ^{k-1}}$.

where

• ${\displaystyle p}$ is the pressure

• ${\displaystyle V}$ is the volume

• ${\displaystyle N}$ is the number of molecules

• ${\displaystyle \rho \equiv {\frac {N}{V}}}$ is the (number) density

• ${\displaystyle B_{k}\left(T\right)}$ is called the k-th virial coefficient

Virial coefficients

The second virial coefficient represents the initial departure from ideal-gas behavior

${\displaystyle B_{2}(T)={\frac {N_{0}}{2V}}\int ....\int (1-e^{-u/kT})~d\tau _{1}d\tau _{2}}$

where ${\displaystyle N_{0}}$ is Avogadros number and ${\displaystyle d\tau _{1}}$ and ${\displaystyle d\tau _{2}}$ are volume elements of two different molecules in configuration space. The integration is to be performed over all available phase-space; that is, over the volume of the containing vessel. For the special case where the molecules posses spherical symmetry, so that ${\displaystyle u}$ depends not on orientation, but only on the separation ${\displaystyle r}$ of a pair of molecules, the equation can be simplified to

${\displaystyle B_{2}(T)=-{\frac {1}{2}}\int _{0}^{\infty }\left(\langle \exp \left(-{\frac {u(r)}{k_{B}T}}\right)\rangle -1\right)4\pi r^{2}dr}$

Using the Mayer f-function

${\displaystyle f_{ij}=f(r_{ij})=\exp \left(-{\frac {u(r)}{k_{B}T}}\right)-1}$

one can write the third virial coefficient more compactly as

${\displaystyle B_{3}(T)=-{\frac {1}{3V}}\int \int \int f_{12}f_{13}f_{23}dr_{1}dr_{2}dr_{3}}$

References

1. James A Beattie and Walter H Stockmayer "Equations of state",Reports on Progress in Physics 7 pp. 195-229 (1940)