Computational implementation of integral equations

Integral equations are solved numerically. One has the Ornstein-Zernike relation, ${\displaystyle \gamma (12)}$ and a closure relation, ${\displaystyle c_{2}(12)}$ (which incorporates the bridge function ${\displaystyle B(12)}$). The numerical solution is iterative;

1. trial solution for ${\displaystyle \gamma (12)}$
2. calculate ${\displaystyle c_{2}(12)}$
3. use the Ornstein-Zernike relation to generate a new ${\displaystyle \gamma (12)}$ etc.

Note that the value of ${\displaystyle c_{2}(12)}$ is local, i.e. the value of ${\displaystyle c_{2}(12)}$ at a given point is given by the value of ${\displaystyle \gamma (12)}$ at this point. However, the Ornstein-Zernike relation is non-local. The way to convert the Ornstein-Zernike relation into a local equation is to perform a (fast) Fourier transform (FFT). Note: convergence is poor for liquid densities. (See Ref.s 1 to 6).

Picard iteration

Picard iteration generates a solution of an initial value problem for an ordinary differential equation (ODE) using fixed-point iteration. Here are the four steps used to solve integral equations:

Closure relation ${\displaystyle \gamma _{mns}^{\mu \nu }(r)\rightarrow c_{mns}^{\mu \nu }(r)}$

(Note: for linear fluids ${\displaystyle \mu =\nu =0}$)

Perform the summation

${\displaystyle g(12)=g(r_{12},\omega _{1},\omega _{2})=\sum _{mns\mu \nu }g_{mns}^{\mu \nu }(r_{12})\Psi _{\mu \nu s}^{mn}(\omega _{1},\omega _{2})}$

where ${\displaystyle r_{12}}$ is the separation between molecular centers and ${\displaystyle \omega _{1},\omega _{2}}$ the sets of Euler angles needed to specify the orientations of the two molecules, with

${\displaystyle \Psi _{\mu \nu s}^{mn}(\omega _{1},\omega _{2})={\sqrt {(2m+1)(2n+1)}}{\mathcal {D}}_{s\mu }^{m}(\omega _{1}){\mathcal {D}}_{{\overline {s}}\nu }^{n}(\omega _{2})}$

with ${\displaystyle {\overline {s}}=-s}$.

Define the variables

${\displaystyle \left.x_{1}\right.=\cos \theta _{1}}$

${\displaystyle \left.x_{2}\right.=\cos \theta _{2}}$

${\displaystyle \left.z_{1}\right.=\cos \chi _{1}}$

${\displaystyle \left.z_{2}\right.=\cos \chi _{2}}$

${\displaystyle \left.y\right.=\cos \phi _{12}}$

Thus

${\displaystyle \left.\gamma (12)\right.=\gamma (r,x_{1}x_{2},y,z_{1}z_{2})}$.

Evaluate

Evaluations of ${\displaystyle \gamma (12)}$ are performed at the discrete points ${\displaystyle x_{i_{1}}x_{i_{2}},y_{j},z_{k_{1}}z_{k_{2}}}$ where the ${\displaystyle x_{i}}$ are the ${\displaystyle \nu }$ roots of the Legendre polynomial ${\displaystyle P_{\nu }(cos\theta )}$ where ${\displaystyle y_{j}}$ are the ${\displaystyle \nu }$ roots of the Chebyshev polynomial ${\displaystyle T_{\nu }(\ cos\phi )}$ and where ${\displaystyle z_{1_{k}},z_{2_{k}}}$ are the ${\displaystyle \nu }$ roots of the Chebyshev polynomial ${\displaystyle T_{\nu }(\ cos\chi )}$ thus

${\displaystyle \gamma (r,x_{1_{i}},x_{2_{i}},j,z_{1_{k}},z_{2_{k}})=\sum _{\nu ,\mu ,s=-M}^{M}\sum _{m=L_{2}}^{M}\sum _{n=L_{1}}^{M}\gamma _{mns}^{\mu \nu }(r){\hat {d}}_{s\mu }^{m}(x_{1_{i}}){\hat {d}}_{{\overline {s}}\nu }^{n}(x_{2_{i}})e_{s}(j)e_{\mu }(z_{1_{k}})e_{\nu }(z_{2_{k}})}$

where

${\displaystyle {\hat {d}}_{s\mu }^{m}(x)=(2m+1)^{1/2}d_{s\mu }^{m}(\theta )}$

where ${\displaystyle d_{s\mu }^{m}(\theta )}$ is the angular, ${\displaystyle \theta }$, part of the rotation matrix ${\displaystyle {\mathcal {D}}_{s\mu }^{m}(\omega )}$, and

${\displaystyle \left.e_{s}(y)\right.=\exp(is\phi )}$

${\displaystyle \left.e_{\mu }(z)\right.=\exp(i\mu \chi )}$

For the limits in the summations

${\displaystyle \left.L_{1}\right.=\max(s,\nu _{1})}$

${\displaystyle \left.L_{2}\right.=\max(s,\nu _{2})}$

The above equation constitutes a separable five-dimensional transform. To rapidly evaluate this expression it is broken down into five one-dimensional transforms:

${\displaystyle \gamma _{l_{2}m}^{n_{1}n_{2}}(r,x_{1_{i}})=\sum _{l_{1}=L_{1}}^{M}\gamma _{l_{1}l_{2}m}^{n_{1}n_{2}}(r){\hat {d}}_{mn_{1}}^{l_{1}}(x_{1_{i}})}$

${\displaystyle \gamma _{m}^{n_{1}n_{2}}(r,x_{1_{i}},x_{2_{i}})=\sum _{l_{2}=L_{2}}^{M}\gamma _{l_{2}m}^{n_{1}n_{2}}(r,x_{1_{i}}){\hat {d}}_{{\overline {m}}n_{2}}^{l_{2}}(x_{2_{i}})}$

${\displaystyle \gamma ^{n_{1}n_{2}}(r,x_{1_{i}},x_{2_{i}},j)=\sum _{m=-M}^{M}\gamma _{m}^{n_{1}n_{2}}(r,x_{1_{i}},x_{2_{i}})e_{m}(j)}$

${\displaystyle \gamma ^{n_{2}}(r,x_{1_{i}},x_{2_{i}},z_{1_{k}})=\sum _{n_{1}=-M}^{M}\gamma ^{n_{1}n_{2}}(r,x_{1_{i}},x_{2_{i}},j)e_{n_{1}}(z_{1_{k}})}$

${\displaystyle \gamma (r,x_{1_{i}},x_{2_{i}},z_{1_{k}},z_{2_{k}})=\sum _{n_{2}=-M}^{M}\gamma ^{n_{2}}(r,x_{1_{i}},x_{2_{i}},j,z_{1_{k}})e_{n_{2}}(z_{2_{k}})}$

Operations involving the ${\displaystyle e_{m}(y)}$ and ${\displaystyle e_{n}(z)}$ basis functions are performed in complex arithmetic. The sum of these operations is asymptotically smaller than the previous expression and thus constitutes a ``fast separable transform". ${\displaystyle NG}$ and ${\displaystyle M}$ are parameters; ${\displaystyle NG}$ is the number of nodes in the Gauss integration, and ${\displaystyle M}$ the the max index in the truncated rotational invariants expansion.

Integrate over angles ${\displaystyle c_{2}(12)}$

Use Gauss-Legendre quadrature for ${\displaystyle x_{1}}$ and ${\displaystyle x_{2}}$ Use Gauss-Chebyshev quadrature for ${\displaystyle y}$, ${\displaystyle z_{1}}$ and ${\displaystyle z_{2}}$. Thus

${\displaystyle c_{mns}^{\mu \nu }(r)=w^{3}\sum _{x_{1_{i}},x_{2_{i}},j,z_{1_{k}},z_{2_{k}}=1}^{NG}w_{i_{1}}w_{i_{2}}c_{2}(r,x_{1_{i}},x_{2_{i}},j,z_{1_{k}},z_{2_{k}}){\hat {d}}_{s\mu }^{m}(x_{1_{i}}){\hat {d}}_{{\overline {s}}\nu }^{n}(x_{2_{i}})e_{\overline {s}}(j)e_{\overline {\mu }}(z_{1_{k}})e_{\overline {\nu }}(z_{2_{k}})}$

where the Gauss-Legendre quadrature weights are given by

${\displaystyle w_{i}={\frac {1}{(1-x_{i}^{2})}}[P_{NG}^{'}(x_{i})]^{2}}$

while the Gauss-Chebyshev quadrature has the constant weight

${\displaystyle w={\frac {1}{NG}}}$

Perform FFT from Real to Fourier space ${\displaystyle c_{mns}^{\mu \nu }(r)\rightarrow {\tilde {c}}_{mns}^{\mu \nu }(k)}$

This is non-trivial and is undertaken in three steps:

Conversion from axial reference frame to spatial reference frame

${\displaystyle c_{mns}^{\mu \nu }(r)\rightarrow c_{\mu \nu }^{mnl}(r)}$

this is done using the Blum transformation (Refs 7, 8 and 9):

${\displaystyle g_{\mu \nu }^{mnl}(r)=\sum _{s=-\min(m,n)}^{\min(m,n)}\left({\begin{array}{ccc}m&n&l\\s&{\overline {s}}&0\end{array}}\right)g_{mns}^{\mu \nu }(r)}$

Fourier-Bessel Transforms

${\displaystyle c_{\mu \nu }^{mnl}(r)\rightarrow {\tilde {c}}_{\mu \nu }^{mnl}(k)}$

${\displaystyle {\tilde {c}}_{\mu \nu }^{mnl}(k;l_{1}l_{2}ln_{1}n_{2})=4\pi i^{l}\int _{0}^{\infty }c_{\mu \nu }^{mnl}(r;l_{1}l_{2}ln_{1}n_{2})J_{l}(kr)~r^{2}{\rm {d}}r}$

(see Blum and Torruella Eq. 5.6 in Ref. 7 or Lado Eq. 39 in Ref. 3), where ${\displaystyle J_{l}(x)}$ is a Bessel function of order ${\displaystyle l}$. `step-down' operations can be performed by way of sin and cos operations of Fourier transforms, see Eqs. 49a, 49b, 50 of Lado Ref. 3. The Fourier-Bessel transform is also known as a Hankel transform. It is equivalent to a two-dimensional Fourier transform with a radially symmetric integral kernel.

${\displaystyle g(q)=2\pi \int _{0}^{\infty }f(r)J_{0}(2\pi qr)r~{\rm {d}}r}$

${\displaystyle f(r)=2\pi \int _{0}^{\infty }g(q)J_{0}(2\pi qr)q~{\rm {d}}q}$

Conversion from the spatial reference frame back to the axial reference frame

${\displaystyle {\tilde {c}}_{\mu \nu }^{mnl}(k)\rightarrow {\tilde {c}}_{mns}^{\mu \nu }(k)}$

this is done using the Blum transformation

${\displaystyle g_{mns}^{\mu \nu }(r)=\sum _{l=|m-n|}^{m+n}\left({\begin{array}{ccc}m&n&l\\s&{\overline {s}}&0\end{array}}\right)g_{\mu \nu }^{mnl}(r)}$

Ornstein-Zernike relation ${\displaystyle {\tilde {c}}_{mns}^{\mu \nu }(k)\rightarrow {\tilde {\gamma }}_{mns}^{\mu \nu }(k)}$

For simple fluids:

${\displaystyle {\tilde {\gamma }}(k)={\frac {\rho {\tilde {c}}_{2}(k)^{2}}{1-\rho {\tilde {c}}_{2}(k)}}}$

For molecular fluids (see Eq. 19 of Lado Ref. 3)

${\displaystyle {\tilde {\mathbf {S} }}_{m}(k)=(-1)^{m}\rho \left[{\mathbf {I} }-(-1)^{m}\rho {\tilde {\mathbf {C} }}_{m}(k)\right]^{-1}{\tilde {\mathbf {C} }}_{m}(k){\tilde {\mathbf {C} }}_{m}(k)}$

where ${\displaystyle {\tilde {\mathbf {S} }}_{m}(k)}$ and ${\displaystyle {\tilde {\mathbf {C} }}_{m}(k)}$ are matrices with elements ${\displaystyle {\tilde {S}}_{l_{1}l_{2}m}(k),{\tilde {C}}_{l_{1}l_{2}m}(k),l_{1},l_{2}\geq m}$.

For mixtures of simple fluids (see Ref. 10 Juan Antonio Anta PhD thesis pp. 107--109):

${\displaystyle {\tilde {\Gamma }}(k)={\mathbf {D} }\left[{\mathbf {I} }-{\mathbf {D} }{\tilde {\mathbf {C} }}(k)\right]^{-1}{\tilde {\mathbf {C} }}(k){\tilde {\mathbf {C} }}(k)}$

Conversion back from Fourier space to Real space

${\displaystyle {\tilde {\gamma }}_{mns}^{\mu \nu }(k)\rightarrow \gamma _{mns}^{\mu \nu }(r)}$

(basically the inverse of step 2).

Axial reference frame to spatial reference frame

${\displaystyle {\tilde {\gamma }}_{mns}^{\mu \nu }(k)\rightarrow {\tilde {\gamma }}_{\mu \nu }^{mnl}(k)}$

Inverse Fourier-Bessel transform

${\displaystyle {\tilde {\gamma }}_{\mu \nu }^{mnl}(k)\rightarrow \gamma _{\mu \nu }^{mnl}(r)}$

'Step-up' operations are given by Eq. 53 of Ref. 3. The inverse Hankel transform is

${\displaystyle \gamma (r;l_{1}l_{2}ln_{1}n_{2})={\frac {1}{2\pi ^{2}i^{l}}}\int _{0}^{\infty }{\tilde {\gamma }}(k;l_{1}l_{2}ln_{1}n_{2})J_{l}(kr)~k^{2}{\rm {d}}k}$

Change from spatial reference frame back to axial reference frame

${\displaystyle \gamma _{\mu \nu }^{mnl}(r)\rightarrow \gamma _{mns}^{\mu \nu }(r)}$.

Ng acceleration

• Kin-Chue Ng "Hypernetted chain solutions for the classical one-component plasma up to Gamma=7000", Journal of Chemical Physics 61 pp. 2680-2689 (1974)

Angular momentum coupling coefficients

• Taro Tamura "Angular momentum coupling coefficients", Computer Physics Communications 1 pp. 337-342 (1970)
• J. G. Wills "On the evaluation of angular momentum coupling coefficients", omputer Physics Communications 2 pp. 381-382 (1971)

References

1. M. J. Gillan "A new method of solving the liquid structure integral equations" Molecular Physics 38 pp. 1781-1794 (1979)
2. Stanislav Labík, Anatol Malijevský and Petr Voncaronka "A rapidly convergent method of solving the OZ equation", Molecular Physics 56 pp. 709-715 (1985)
3. F. Lado "Integral equations for fluids of linear molecules I. General formulation", Molecular Physics 47 pp. 283-298 (1982)
4. F. Lado "Integral equations for fluids of linear molecules II. Hard dumbell solutions", Molecular Physics 47 pp. 299-311 (1982)
5. F. Lado "Integral equations for fluids of linear molecules III. Orientational ordering", Molecular Physics 47 pp. 313-317 (1982)
6. Enrique Lomba "An efficient procedure for solving the reference hypernetted chain equation (RHNC) for simple fluids" Molecular Physics 68 pp. 87-95 (1989)
7. L. Blum and A. J. Torruella "Invariant Expansion for Two-Body Correlations: Thermodynamic Functions, Scattering, and the Ornstein—Zernike Equation", Journal of Chemical Physics 56 pp. pp. 303-310 (1972)
8. L. Blum "Invariant Expansion. II. The Ornstein-Zernike Equation for Nonspherical Molecules and an Extended Solution to the Mean Spherical Model", Journal of Chemical Physics 57 pp. 1862-1869 (1972)
9. L. Blum "Invariant expansion III: The general solution of the mean spherical model for neutral spheres with electostatic interactions", Journal of Chemical Physics 58 pp. 3295-3303 (1973)
10. P. G. Kusalik and G. N. Patey " On the molecular theory of aqueous electrolyte solutions. I. The solution of the RHNC approximation for models at finite concentration", Journal of Chemical Physics 88 pp. 7715-7738 (1988)