Dieterici equation of state: Difference between revisions

Latest revision as of 15:19, 22 September 2010

The Dieterici equation of state ^[1] is given by

p={\frac {RT}{v-b}}e^{-a/RTv}

where (Eq. 8 in ^[2]):

a={\frac {4R^{2}T_{c}^{2}}{P_{c}e^{2}}}

and

b={\frac {RT_{c}}{P_{c}e^{2}}}

where $p$ is the pressure, $T$ is the temperature and $R$ is the molar gas constant. $T_{c}$ is the critical temperature and $P_{c}$ is the pressure at the critical point.

Sadus modification[edit]

Sadus ^[3] proposed replacing the repulsive section of the Dieterici equation with the Carnahan-Starling equation of state, which is often used to describe the equation of state of the hard sphere model, resulting in (Eq. 5):

p={\frac {RT}{v}}{\frac {(1+\eta +\eta ^{2}-\eta ^{3})}{(1-\eta )^{3}}}e^{-a/RTv}

where $\eta =b/4v$ is the packing fraction.

This equation gives:

a=2.99679RT_{c}v_{c}

and

\eta _{c}=0.357057

References[edit]

↑ C. Dieterici, Ann. Phys. Chem. Wiedemanns Ann. 69, 685 (1899)
↑ K. K. Shah and G. Thodos "A Comparison of Equations of State", Industrial & Engineering Chemistry 57 pp. 30-37 (1965)
↑ Richard J. Sadus "Equations of state for fluids: The Dieterici approach revisited", Journal of Chemical Physics 115 pp. 1460-1462 (2001)

[1] C. Dieterici, Ann. Phys. Chem. Wiedemanns Ann. 69, 685 (1899)

[2] K. K. Shah and G. Thodos "A Comparison of Equations of State", Industrial & Engineering Chemistry 57 pp. 30-37 (1965)

[3] Richard J. Sadus "Equations of state for fluids: The Dieterici approach revisited", Journal of Chemical Physics 115 pp. 1460-1462 (2001)

[1]

[2]

[3]

@@ Line 1: / Line 1: @@
-:<math>\left. p(v-b) \right.= kT e^{-a/kTv}</math>
+The '''Dieterici''' [[Equations of state |equation of state]] <ref>C. Dieterici, Ann. Phys. Chem. Wiedemanns Ann. 69, 685 (1899)</ref> is given by
+:<math>p =  \frac{RT}{v-b} e^{-a/RTv}</math>
+where (Eq. 8 in <ref>[http://dx.doi.org/10.1021/ie50663a005 K. K. Shah and G. Thodos "A Comparison of Equations of State", Industrial & Engineering Chemistry '''57''' pp. 30-37 (1965)]</ref>):
+:<math>a = \frac{4R^2T_c^2}{P_ce^2}</math>
+and
+:<math>b=\frac{RT_c}{P_ce^2}</math>
+where <math>p</math> is the [[pressure]], <math>T</math> is the [[temperature]] and <math>R</math> is the [[molar gas constant]]. <math>T_c</math> is the [[critical points | critical]] temperature and <math>P_c</math> is the [[pressure]] at the critical point.
+==Sadus modification==
+Sadus <ref>[http://dx.doi.org/10.1063/1.1380711 Richard J. Sadus "Equations of state for fluids: The Dieterici approach revisited", Journal of Chemical Physics '''115''' pp. 1460-1462 (2001)]</ref> proposed replacing the repulsive section of the Dieterici equation with the [[Carnahan-Starling equation of state]], which is often used to describe the equation of state of the [[hard sphere model]], resulting in (Eq. 5):
+:<math>p = \frac{RT}{v} \frac{(1 + \eta + \eta^2 - \eta^3)}{(1-\eta)^3 }  e^{-a/RTv}</math>
+where <math> \eta = b/4v </math> is the [[packing fraction]].
+This equation gives:
+:<math>a = 2.99679 R T_c  v_c</math>
+and
+:<math>\eta_c = 0.357057</math>
+==References==
+<references/>
-where <math>a</math> is an empirical constant.
 [[category: equations of state]]

Dieterici equation of state: Difference between revisions

Latest revision as of 15:19, 22 September 2010

Sadus modification[edit]

References[edit]

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