Vega equation of state for hard ellipsoids: Difference between revisions

Revision as of 11:17, 12 July 2007

The Vega equation of state for an isotropic fluid of hard (biaxial) ellipsoids is given by (Ref. 1 Eq. 20):

Z=1+B_{2}^{*}y+B_{3}^{*}y^{2}+B_{4}^{*}y^{3}+B_{5}^{*}y^{4}+{\frac {B_{2}}{4}}\left({\frac {1+y+y^{2}-y^{3}}{(1-y)^{3}}}-1-4y-10y^{2}-18.3648y^{3}-28.2245y^{4}\right)

where $Z$ is the compressibility factor and $y$ is the volume fraction, given by $y=\rho V$ where $\rho$ is the number density. The virial coefficients are given by the fits

B_{3}^{*}=10+13.094756\alpha '-2.073909\tau '+4.096689\alpha '^{2}+2.325342\tau '^{2}-5.791266\alpha '\tau ',

B_{4}^{*}=18.3648+27.714434\alpha '-10.2046\tau '+11.142963\alpha '^{2}+8.634491\tau '^{2}-28.279451\alpha '\tau '-17.190946\alpha '^{2}\tau '+24.188979\alpha '\tau '^{2}+0.74674\alpha '^{3}-9.455150\tau '^{3},

and

B_{5}^{*}=28.2245+21.288105\alpha '+4.525788\tau '+36.032793\alpha '^{2}+59.0098\tau '^{2}-118.407497\alpha '\tau '+24.164622\alpha '^{2}\tau '+139.766174\alpha '\tau '^{2}-50.490244\alpha '^{3}-120.995139\tau '^{3}+12.624655\alpha '^{3}\tau ',

where

B_{n}^{*}=B_{n}/V^{n-1}

,

\tau '={\frac {4\pi R^{2}}{S}}-1,

and

\alpha '={\frac {RS}{3V}}-1.

where $V$ is the volume, $S$ , the surface area, and $R$ the mean radius of curvature.

For $B_{2}$ see the page "Second virial coefficient".

@@ Line 41: / Line 41: @@
 the volume, <math>S</math>, the surface area,  and <math>R</math> the mean radius of curvature.
-For  <math>B_2</math> see [[B_2 for any hard convex body]].
+For  <math>B_2</math> see the page "[[Second virial coefficient]]".
 ==References==
 #[http://dx.doi.org/10.1080/002689797169934 Carlos Vega "Virial coefficients and equation of state of hard ellipsoids", Molecular Physics '''92''' pp. 651-665 (1997)]