Exact solution of the Percus Yevick integral equation for hard spheres: Difference between revisions

The exact solution for the Percus Yevick integral equation for hard spheres was derived by M. S. Wertheim in 1963 Ref. 1 (See also Ref. 2) (and for mixtures by in Lebowitz 1964 Ref. 3). The direct correlation function is given by (Ref. 1 Eq. 6)

${\displaystyle C(r/R)=-{\frac {(1+2\eta )^{2}-6\eta (1+{\frac {1}{2}}\eta )^{2}(r/R)+\eta (1+2\eta )^{2}{\frac {(r/R)^{3}}{2}}}{(1-\eta )^{4}}}}$

where

${\displaystyle \eta ={\frac {1}{6}}\pi R^{3}\rho }$

and R is the hard sphere diameter. The equation of state is (Ref. 1 Eq. 7)

${\displaystyle \beta P\rho ={\frac {(1+\eta +\eta ^{2})}{(1-\eta )^{3}}}}$

Everett Thiele (1963 Ref. 4}) also studied this system, resulting in (Eq. 23)

${\displaystyle \left.h_{0}(r)\right.=ar+br^{2}+cr^{4}}$

where (Eq. 24)

${\displaystyle a={\frac {(2x+1)^{2}}{(x-1)^{4}}}}$

and

${\displaystyle b=-{\frac {12x+12x^{2}+3x^{3}}{2(x-1)^{4}}}}$

and

${\displaystyle c={\frac {x(2x+1)^{2}}{2(x-1)^{4}}}}$

and where ${\displaystyle x=\rho /4}$. The pressure via the pressure route (Eq.s 32 and 33) is

${\displaystyle P=nkT{\frac {(1+2x+3x^{2})}{(1-x)^{2}}}}$

and the compressibility route is

${\displaystyle P=nkT{\frac {(1+x+x^{2})}{(1-x)^{3}}}}$

References

1. M. S. Wertheim "Exact Solution of the Percus-Yevick Integral Equation for Hard Spheres", Physical Review Letters 10 321 - 323 (1963)
2. [http://dx.doi.org/
3. J. L. Lebowitz, "Exact Solution of Generalized Percus-Yevick Equation for a Mixture of Hard Spheres", Physical Review 133 pp. A895 - A899 (1964)
4. [http://dx.doi.org/
5. [JMP_1964_05_00643]
6. [JCP_1963_39_00474]