Ornstein-Zernike relation: Difference between revisions

Latest revision as of 14:17, 21 December 2016

Notation used:

$g(r)$ is the pair distribution function.
$\Phi (r)$ is the pair potential acting between pairs.
$h(1,2)$ is the total correlation function.
$c(1,2)$ is the direct correlation function.
$\gamma (r)$ is the indirect (or series or chain) correlation function.
$y(r_{12})$ is the cavity correlation function.
$B(r)$ is the bridge function.
$\omega (r)$ is the thermal potential.
$f(r)$ is the Mayer f-function.

The Ornstein-Zernike relation integral equation ^[1] is given by:

h=h\left[c\right]

where $h[c]$ denotes a functional of $c$ . This relation is exact. This is complemented by the closure relation

c=c\left[h\right]

Note that $h$ depends on $c$ , and $c$ depends on $h$ . Because of this $h$ must be determined self-consistently. This need for self-consistency is characteristic of all many-body problems. (Hansen and McDonald, section 5.2 p. 106) For a system in an external field, the Ornstein-Zernike relation has the form (5.2.7)

h(1,2)=c(1,2)+\int \rho ^{(1)}(3)c(1,3)h(3,2)d3

If the system is both homogeneous and isotropic, the Ornstein-Zernike relation becomes (Eq. 6 of Ref. 1)

\gamma ({\mathbf {r} })\equiv h({\mathbf {r} })-c({\mathbf {r} })=\rho \int h({\mathbf {r} '})~c(|{\mathbf {r} }-{\mathbf {r} '}|){\rm {d}}{\mathbf {r} '}

In words, this equation (Hansen and McDonald, section 5.2 p. 107)

"...describes the fact that the total correlation between particles 1 and 2, represented by

h(1,2)

, is due in part to the direct correlation between 1 and 2, represented by

c(1,2)

, but also to the indirect correlation,

\gamma (r)

, propagated via increasingly large numbers of intermediate particles."

Notice that this equation is basically a convolution, i.e.

h\equiv c+\rho h\otimes c

(Note: the convolution operation written here as $\otimes$ is more frequently written as $*$ ) This can be seen by expanding the integral in terms of $h(r)$ (here truncated at the fourth iteration):

h({\mathbf {r} })=c({\mathbf {r} })+\rho \int c(|{\mathbf {r} }-{\mathbf {r} '}|)c({\mathbf {r} '}){\rm {d}}{\mathbf {r} '}

+\rho ^{2}\iint c(|{\mathbf {r} }-{\mathbf {r} '}|)c(|{\mathbf {r} '}-{\mathbf {r} ''}|)c({\mathbf {r} ''}){\rm {d}}{\mathbf {r} ''}{\rm {d}}{\mathbf {r} '}

+\rho ^{3}\iiint c(|{\mathbf {r} }-{\mathbf {r} '}|)c(|{\mathbf {r} '}-{\mathbf {r} ''}|)c(|{\mathbf {r} ''}-{\mathbf {r} '''}|)c({\mathbf {r} '''}){\rm {d}}{\mathbf {r} '''}{\rm {d}}{\mathbf {r} ''}{\rm {d}}{\mathbf {r} '}

+\rho ^{4}\iiiint c(|{\mathbf {r} }-{\mathbf {r} '}|)c(|{\mathbf {r} '}-{\mathbf {r} ''}|)c(|{\mathbf {r} ''}-{\mathbf {r} '''}|)c(|{\mathbf {r} '''}-{\mathbf {r} ''''}|)h({\mathbf {r} ''''}){\rm {d}}{\mathbf {r} ''''}{\rm {d}}{\mathbf {r} '''}{\rm {d}}{\mathbf {r} ''}{\rm {d}}{\mathbf {r} '}

etc.

Diagrammatically this expression can be written as ^[2]:

where the bold lines connecting root points denote $c$ functions, the blobs denote $h$ functions. An arrow pointing from left to right indicates an uphill path from one root point to another. An `uphill path' is a sequence of Mayer bonds passing through increasing particle labels. The Ornstein-Zernike relation can be derived by performing a functional differentiation of the grand canonical distribution function.

Ornstein-Zernike relation in Fourier space[edit]

The Ornstein-Zernike equation may be written in Fourier space as (^[3] Eq. 5):

{\hat {\gamma }}=(\mathbf {I} -\rho \mathbf {\hat {c}} )^{-1}\mathbf {\hat {c}} \rho \mathbf {\hat {c}}

The carets denote the three-dimensional Fourier transformed quantities which reduce explicitly to:

{\hat {\gamma }}(k)={\frac {4\pi }{k}}\int _{0}^{\infty }r~\sin(kr)\gamma (r)dr

\gamma (r)={\frac {1}{2\pi ^{2}r}}\int _{0}^{\infty }k~\sin(kr){\hat {\gamma }}(k)dk

Note:

{\hat {h}}(0)=\int h(r){\rm {d}}{\mathbf {r} }

{\hat {c}}(0)=\int c(r){\rm {d}}{\mathbf {r} }

References[edit]

↑ L. S. Ornstein and F. Zernike "Accidental deviations of density and opalescence at the critical point of a single substance", Koninklijke Nederlandse Akademie van Wetenschappen Amsterdam Proc. Sec. Sci. 17 pp. 793- (1914)
↑ James A. Given "Liquid-state methods for random media: Random sequential adsorption", Physical Review A 45 pp. 816-824 (1992)
↑ Der-Ming Duh and A. D. J. Haymet "Integral equation theory for uncharged liquids: The Lennard-Jones fluid and the bridge function", Journal of Chemical Physics 103 pp. 2625-2633 (1995)

Related reading

Jean-Pierre Hansen and I.R. McDonald "Theory of Simple Liquids", Academic Press (2006) (Third Edition) ISBN 0-12-370535-5 § 3.5
Yan He, Stuart A. Rice, and Xinliang Xu "Analytic solution of the Ornstein-Zernike relation for inhomogeneous liquids", Journal of Chemical Physics 145 234508 (2016)

[1] L. S. Ornstein and F. Zernike "Accidental deviations of density and opalescence at the critical point of a single substance", Koninklijke Nederlandse Akademie van Wetenschappen Amsterdam Proc. Sec. Sci. 17 pp. 793- (1914)

[2] James A. Given "Liquid-state methods for random media: Random sequential adsorption", Physical Review A 45 pp. 816-824 (1992)

[3] Der-Ming Duh and A. D. J. Haymet "Integral equation theory for uncharged liquids: The Lennard-Jones fluid and the bridge function", Journal of Chemical Physics 103 pp. 2625-2633 (1995)

[1]

[2]

[3]

@@ Line 82: / Line 82: @@
 '''Related reading'''
 *Jean-Pierre Hansen and I.R. McDonald "Theory of Simple Liquids", Academic Press (2006) (Third Edition) ISBN 0-12-370535-5 &sect; 3.5
+*[http://doi.org/10.1063/1.4972020 Yan He, Stuart A. Rice, and Xinliang Xu "Analytic solution of the Ornstein-Zernike relation for inhomogeneous liquids", Journal of Chemical Physics  '''145''' 234508 (2016)]
 [[Category: Integral equations]]

Ornstein-Zernike relation: Difference between revisions

Latest revision as of 14:17, 21 December 2016

Ornstein-Zernike relation in Fourier space[edit]

References[edit]

Navigation menu

Search