Isothermal-isobaric ensemble: Difference between revisions

Revision as of 12:03, 27 February 2007

Ensemble variables:

The classical partition function, for a one-component atomic system in 3-dimensional space, is given by

Q_{NpT}={\frac {\beta p}{\Lambda ^{3}N!}}\int _{0}^{\infty }dVV^{N}\exp \left[-\beta pV\right]\int d(R^{*})^{3N}\exp \left[-\beta U\left(V,(R^{*})^{3N}\right)\right]

where

$\left(R^{*}\right)^{3N}$ represent the reduced position coordinates of the particles; i.e. $\int d(R^{*})^{3N}=1$

$\left.U\right.$ is the potential energy, which is a function of the coordinates (or of the volume and the reduced coordinates)

D. Frenkel and B. Smit, "Understanding Molecular Simulation: From Alogrithms to Applications", Academic Press

@@ Line 1: / Line 1: @@
-Variables:
+Ensemble variables:
 * N (Number of particles)
 * p (Pressure)
 * T (Temperature)
-* V (Volume)
 The [[classical partition function]], for a one-component atomic system in 3-dimensional space, is given by
@@ Line 12: / Line 11: @@
 where
+* <math> \left. V \right. </math> is the Volume:
 *<math> \beta = \frac{1}{k_B T} </math>;
-*<math> \Lambda </math> is the [[de Broglie wavelength]]
+*<math> \left. \Lambda \right. </math> is the [[de Broglie wavelength]]
 *<math> \left( R^* \right)^{3N} </math> represent the reduced position coordinates of the particles; i.e. <math> \int d ( R^*)^{3N}  = 1 </math>