MOZ

The Ornstein-Zernike equations for mixtures of monomers with coincident oligomers (coincident dimers, trimers,...,n-mers).

${\displaystyle h_{an}(r)-c_{an}(r)=\int h_{aa}(r')~\rho _{a}~c_{an}(|r-r'|)dr'~~~~~n=a,2,3,...}$

Since all oligomers are at infinite dilution, the OZ's for all $n>1$ are decoupled. The first member is for the bulk monomer fluid a (with size ${\displaystyle \sigma }$ and energy ${\displaystyle \epsilon }$)

${\displaystyle h_{aa}(r)-c_{aa}(r)=\int h_{aa}(r')~\rho _{a}~c_{aa}(|r-r'|)dr'}$

For a coincident dimer (${\displaystyle n=2}$) of size ${\displaystyle \sigma }$ and energy ${\displaystyle 2\epsilon }$ at infinite dilution in the bulk a-monomers:

${\displaystyle h_{a2}(r)-c_{a2}(r)=\int h_{aa}(r')~\rho _{a}~c_{a2}(|r-r'|)dr'}$

For a coincident trimer (${\displaystyle n=3}$) of size ${\displaystyle \sigma }$ and energy ${\displaystyle 3\epsilon }$ at infinite dilution in the bulk a-monomers:

${\displaystyle h_{a3}(r)-c_{a3}(r)=\int h_{aa}(r')~\rho _{a}~c_{a3}(|r-r'|)dr'}$