Ornstein-Zernike relation from the grand canonical distribution function

Defining the local activity by $z(r)=z\exp[-\beta \psi (r)]$ where $\beta =1/k_{B}T$ , and $k_{B}$ is the Boltzmann constant. Using those definitions the grand canonical partition function can be written as

\Xi =\sum _{N}^{\infty }{1 \over N!}\int \dots \int \prod _{i}^{N}z(r_{i})\exp(-\beta U_{N})dr_{1}\dots dr_{N}

.

By functionally-differentiating $\Xi$ with respect to $z(r)$ , and utilizing the mathematical theorem concerning the functional derivative,

{\delta z(r) \over {\delta z(r')}}=\delta (r-r')

,

we get the following equations with respect to the density pair correlation functions.

\rho (r)={\delta \ln \Xi  \over {\delta \ln z(r)}}

,

\rho ^{(2)}(r,r')={\delta ^{2}\ln \Xi  \over {\delta \ln z(r)\delta \ln z(r')}}

.

A relation between $\rho (r)$ and $\rho ^{(2)}(r,r')$ can be obtained after some manipulation as,

{\delta \rho ({\bf {r}}) \over {\delta \ln z({\bf {r'}})}}=\rho ^{(2)}({\bf {r,r'}})-\rho ({\bf {r}})\rho ({\bf {r'}})+\delta ({\bf {r}}-{\bf {r'}})\rho ({\bf {r}}).

Now, we define the direct correlation function by an inverse relation of Eq. (\ref{deltarho}),

Failed to parse (unknown function "\label"): {\displaystyle {\delta \ln z({\bf r})\over{\delta\rho({\bf r'})}}={\delta({\bf r}-{\bf r'})\over{\rho({\bf r'})}} \label{deltalnz}-c({\bf r,r'}).}

Inserting Eqs. (\ref{deltarho}) and (\ref{deltalnz}) into the chain-rule theorem of functional derivatives,

\int {\delta \rho ({\bf {r}}) \over {\delta \ln z({\bf {r}}^{\prime \prime })}}{\delta \ln z({\bf {r}}^{\prime \prime }) \over {\delta \rho ({\bf {r'}})}}{\rm {d}}{\bf {r}}^{\prime \prime }=\delta ({\bf {r}}-{\bf {r'}}),

one obtains the Ornstein-Zernike relation. Thus the Ornstein-Zernike relation is, in a sense, a differential form of the partition function.

Ornstein-Zernike relation from the grand canonical distribution function

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