Mean spherical approximation

The Lebowitz and Percus mean spherical approximation (MSA) (1966) (Ref. 1) closure is given by

${\displaystyle c(r)=-\beta \omega (r),~~~~r>\sigma .}$

The Blum and Hoye mean spherical approximation (MSA) (1978-1980) (Refs 2 and 3) closure is given by

${\displaystyle {\rm {g}}_{ij}(r)\equiv h_{ij}(r)+1=0~~~~~~~~r<\sigma _{ij}=(\sigma _{i}+\sigma _{j})/2}$

and

${\displaystyle c_{ij}(r)=\sum _{n=1}{\frac {K_{ij}^{(n)}}{r}}e^{-z_{n}r}~~~~~~\sigma _{ij}<r}$

where ${\displaystyle h_{ij}(r)}$ and ${\displaystyle c_{ij}(r)}$ are the total and the direct correlation functions for two spherical molecules of i and j species, ${\displaystyle \sigma _{i}}$ is the diameter of 'i species of molecule. Duh and Haymet (Eq. 9 Ref. 4) write the MSA approximation as

${\displaystyle g(r)={\frac {c(r)+\beta \Phi _{2}(r)}{1-e^{\beta \Phi _{1}(r)}}}}$

where ${\displaystyle \Phi _{1}}$ and ${\displaystyle \Phi _{2}}$ comes from the WCA division of the Lennard-Jones potential. By introducing the definition (Eq. 10 Ref. 4)

${\displaystyle \left.s(r)\right.=h(r)-c(r)-\beta \Phi _{2}(r)}$

one can arrive at (Eq. 11 \cite{JCP_1995_103_02625})

${\displaystyle B(r)\approx B^{\rm {MSA}}(s)=\ln(1+s)-s}$

The Percus Yevick approximation may be recovered from the above equation by setting ${\displaystyle \Phi _{2}=0}$.

References

1. [PR_1966_144_000251]
2. [JSP_1978_19_0317_nolotengoSpringer]
3. [JSP_1980_22_0661_nolotengoSpringer]
4. [JCP_1995_103_02625]