Pair distribution function: Difference between revisions

For a fluid of ${\displaystyle N}$ particles, enclosed in a volume ${\displaystyle V}$ at a given temperature ${\displaystyle T}$ (canonical ensemble) interacting via the `central' intermolecular pair potential ${\displaystyle \Phi (r)}$, the two particle distribution function is defined as

${\displaystyle {\rm {g}}_{N}^{(2)}({\mathbf {r} }_{1},{\mathbf {r} }_{2})=V^{2}{\frac {\int ...\int e^{-\beta \Phi ({\mathbf {r} }_{1},...,{\mathbf {r} }_{N})}{\rm {d}}{\mathbf {r} }_{3}...{\rm {d}}{\mathbf {r} }_{N}}{\int e^{-\beta \Phi ({\mathbf {r} }_{1},...,{\mathbf {r} }_{N})}{\rm {d}}{\mathbf {r} }_{1}...{\rm {d}}{\mathbf {r} }_{N}}}}$

where ${\displaystyle \beta =1/(k_{B}T)}$, where ${\displaystyle k_{B}}$ is the Boltzmann constant.

Exact convolution equation for ${\displaystyle g(r)}$

See Eq. 5.10 of Ref. 1:

${\displaystyle \ln g(r_{12})+{\frac {\Phi (r_{12})}{kT}}-E(r_{12})=n\int \left(g(r_{13})-1-\ln g(r_{13})-{\frac {\Phi (r_{13})}{kT}}-E(r_{13})\right)(g(r_{23})-1)~{\rm {d}}{\mathbf {r} }_{3}}$

where, i.e. ${\displaystyle r_{12}=|{\mathbf {r} }_{2}-{\mathbf {r} }_{1}|}$.

See also

• Radial distribution function
• Compressibility equation
• Pressure equation
• Energy equation

References

1. J. S. Rowlinson "The equation of state of dense systems", Reports on Progress in Physics 28 pp. 169-199 (1965)