Berthelot equation of state: Difference between revisions

Revision as of 12:47, 21 September 2010

The Berthelot equation of state ^[1] can be written as

RT=\left(p+{\frac {a}{Tv^{2}}}\right)\left(v-b\right)

.

At the critical point one has $\left.{\frac {\partial p}{\partial v}}\right|_{T=T_{c}}=0$ , and $\left.{\frac {\partial ^{2}p}{\partial v^{2}}}\right|_{T=T_{c}}=0$ , which leads to (Eqs. 4.1 - 4.3 ^[2]^[3])

a=3T_{c}p_{c}v_{c}^{2}

b={\frac {v_{c}}{3}}

and

R={\frac {8p_{c}v_{c}}{3T_{c}}}

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.

References

↑ D. J. Berthelot "Sur Une Méthode Purement Physique Pour La Détermination des Poids Moléculaires des Gaz et des Poids Atomiques de Leurs Éléments", J. Phys., 8 pp. 263-274 (1899)
↑ Antony F. Saturno "Daniel Berthelot's equation of state", Journal of Chemical Education 39 (9) pp. 464-465 (1962)
↑ SAGE Notebook Worksheet for use in the mathematics program SAGE

[1] D. J. Berthelot "Sur Une Méthode Purement Physique Pour La Détermination des Poids Moléculaires des Gaz et des Poids Atomiques de Leurs Éléments", J. Phys., 8 pp. 263-274 (1899)

[2] Antony F. Saturno "Daniel Berthelot's equation of state", Journal of Chemical Education 39 (9) pp. 464-465 (1962)

[3] SAGE Notebook Worksheet for use in the mathematics program SAGE

[1]

[2]

[3]

@@ Line 1: / Line 1: @@
 The '''Berthelot equation of state''' <ref>[http://dx.doi.org/10.1051/jphystap:018990080026300 D. J. Berthelot "Sur Une Méthode Purement Physique Pour La Détermination des Poids Moléculaires des Gaz et des Poids Atomiques de Leurs Éléments", J. Phys., '''8''' pp. 263-274 (1899)]</ref> can be written as
-:<math>RT = \left( p + \frac{a}{Tv^2} \right) \left( v - b\right)</math>
+:<math>RT = \left( p + \frac{a}{Tv^2} \right) \left( v - b\right)</math>.
-where
+At the [[critical points | critical point]] one has <math>\left.\frac{\partial p}{\partial v}\right|_{T=T_c}=0 </math>, and <math>\left.\frac{\partial^2 p}{\partial v^2}\right|_{T=T_c}=0 </math>, which leads to (Eqs. 4.1 - 4.3 <ref>[http://dx.doi.org/10.1021/ed039p464 Antony F. Saturno "Daniel Berthelot's equation of state", Journal of Chemical Education '''39''' (9) pp. 464-465 (1962)]</ref><ref>  [http://www.ucm.es/info/molecsim/Berthelot_EOS.sws SAGE Notebook Worksheet] for use in the mathematics program [http://www.sagemath.org/ SAGE]</ref>)
-:<math>a= \frac{27}{64}R^2 \frac{T_c^3}{P_c}</math>
+:<math>a = 3T_cp_cv_c^2</math>
+:<math>b= \frac{v_c}{3}</math>
 and
-:<math>b=\frac{RT_c}{8P_c}</math>
+:<math>R = \frac{8p_cv_c}{3T_c}</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.
 ==References==
 <references/>
-'''Related reading'''
-*[http://dx.doi.org/10.1021/ed039p464 Antony F. Saturno "Daniel Berthelot's equation of state", Journal of Chemical Education '''39''' (9) pp. 464-465 (1962)]
 [[category: equations of state]]

Berthelot equation of state: Difference between revisions

Revision as of 12:47, 21 September 2010

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