Mean spherical approximation: Difference between revisions
Carl McBride (talk | contribs) m (New page: The '''Lebowitz and Percus''' mean spherical approximation (MSA) (1966) \cite{PR_1966_144_000251} closure is given by <math>c(r) = -\beta \omega(r), ~~~~ r>\sigma.</math> The {\bf Blum a...) |
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The '''Lebowitz and Percus''' mean spherical approximation (MSA) (1966) | The '''Lebowitz and Percus''' mean spherical approximation (MSA) (1966) (Ref. 1) closure is given by | ||
closure is given by | |||
<math>c(r) = -\beta \omega(r), ~~~~ r>\sigma.</math> | :<math>c(r) = -\beta \omega(r), ~~~~ r>\sigma.</math> | ||
The {\bf Blum and H$\o$ye} mean spherical approximation (MSA) (1978-1980) | The {\bf Blum and H$\o$ye} mean spherical approximation (MSA) (1978-1980) | ||
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closure is given by | closure is given by | ||
<math>{\rm g}_{ij}(r) \equiv h_{ij}(r) +1=0 ~~~~~~~~ r < \sigma_{ij} = (\sigma_i + \sigma_j)/2</math> | :<math>{\rm g}_{ij}(r) \equiv h_{ij}(r) +1=0 ~~~~~~~~ r < \sigma_{ij} = (\sigma_i + \sigma_j)/2</math> | ||
and | and | ||
<math>c_{ij}(r)= \sum_{n=1} \frac{K_{ij}^{(n)}}{r}e^{-z_nr} ~~~~~~ \sigma_{ij} < r</math> | :<math>c_{ij}(r)= \sum_{n=1} \frac{K_{ij}^{(n)}}{r}e^{-z_nr} ~~~~~~ \sigma_{ij} < r</math> | ||
where $h_{ij}(r)$ and $c_{ij}(r)$ are the total and the direct correlation functions for two spherical | where $h_{ij}(r)$ and $c_{ij}(r)$ are the total and the direct correlation functions for two spherical | ||
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Duh and Haymet (Eq. 9 \cite{JCP_1995_103_02625}) write the MSA approximation as | Duh and Haymet (Eq. 9 \cite{JCP_1995_103_02625}) write the MSA approximation as | ||
<math>g(r) = \frac{c(r) + \beta \Phi_2(r)}{1-e^{\beta \Phi_1(r)}}</math> | :<math>g(r) = \frac{c(r) + \beta \Phi_2(r)}{1-e^{\beta \Phi_1(r)}}</math> | ||
where $\Phi_1$ and $\Phi_2$ comes from the WCA division of the LJ potential.\\ | where $\Phi_1$ and $\Phi_2$ comes from the WCA division of the LJ potential.\\ | ||
By introducing the definition (Eq. 10 \cite{JCP_1995_103_02625}) | By introducing the definition (Eq. 10 \cite{JCP_1995_103_02625}) | ||
<math>s(r) = h(r) -c(r) -\beta \Phi_2 (r)</math> | :<math>s(r) = h(r) -c(r) -\beta \Phi_2 (r)</math> | ||
one can arrive at (Eq. 11 \cite{JCP_1995_103_02625}) | one can arrive at (Eq. 11 \cite{JCP_1995_103_02625}) | ||
<math>B(r) \approx B^{\rm MSA}(s) = \ln (1+s)-s</math> | :<math>B(r) \approx B^{\rm MSA}(s) = \ln (1+s)-s</math> | ||
The [[Percus Yevick]] approximation may be recovered from the above equation by setting <math>\Phi_2=0</math>. | The [[Percus Yevick]] approximation may be recovered from the above equation by setting <math>\Phi_2=0</math>. | ||
==References== | ==References== | ||
#[PR_1966_144_000251] | |||
Revision as of 13:08, 23 February 2007
The Lebowitz and Percus mean spherical approximation (MSA) (1966) (Ref. 1) closure is given by
The {\bf Blum and H$\o$ye} mean spherical approximation (MSA) (1978-1980) \cite{JSP_1978_19_0317_nolotengoSpringer,JSP_1980_22_0661_nolotengoSpringer} closure is given by
and
where $h_{ij}(r)$ and $c_{ij}(r)$ are the total and the direct correlation functions for two spherical molecules of $i$ and $j$ species, $\sigma_i$ is the diameter of $i$ species of molecule.\\ Duh and Haymet (Eq. 9 \cite{JCP_1995_103_02625}) write the MSA approximation as
where $\Phi_1$ and $\Phi_2$ comes from the WCA division of the LJ potential.\\ By introducing the definition (Eq. 10 \cite{JCP_1995_103_02625})
one can arrive at (Eq. 11 \cite{JCP_1995_103_02625})
The Percus Yevick approximation may be recovered from the above equation by setting .
References
- [PR_1966_144_000251]