Gibbs-Duhem integration: Difference between revisions

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History

The so-called Gibbs-Duhem Integration referes to a number of methods that couple molecular simulation techniques with thermodynamic equations in order to draw phase coexistence lines.

The method was proposed by Kofke (Ref 1-2).

Basic Features

Consider two thermodynamic phases: ${\displaystyle a}$ and ${\displaystyle b}$, at thermodynamic equilibrium at certain conditions. The thermodynamic equilibrium implies:

• Equal temperature in both phases: ${\displaystyle T=T_{a}=T_{b}}$, i.e. thermal equilbirum.
• Equal pressure in both phases ${\displaystyle p=p_{a}=p_{b}}$, i.e. mechanical equilbrium.
• Equal chemical potentials for the components ${\displaystyle \mu _{i}=\mu _{ia}=\mu _{ib}}$, i.e. material equilibrium.

In addition if we are dealing with a statistical mechanics model, with certain parameters that we can represent as ${\displaystyle \lambda }$ , the model should be the same in both phases.

Example: phase equilibria of one-component system

Notice: The derivation that follows is just a particular route to perform the integration

• Consider that at given conditions of ${\displaystyle T,p,\lambda }$ two phases of the systems are at equilibrium, this implies:

${\displaystyle \mu _{a}\left(T,p,\lambda \right)=\mu _{b}\left(T,p,\lambda \right)}$

Given the thermal equilibrium we can also write:

${\displaystyle \beta \mu _{a}\left(\beta ,\beta p,\lambda \right)=\beta \mu _{b}\left(\beta ,\beta p,\lambda \right)}$

where

• ${\displaystyle \beta =1/k_{B}T}$, where ${\displaystyle k_{B}}$ is the Boltzmann constant

When a differential change of the conditions is performed we wil have for any phase:

${\displaystyle d\left(\beta \mu \right)=\left[{\frac {\partial (\beta \mu )}{\partial \beta }}\right]_{\beta p,\lambda }d\beta +\left[{\frac {\partial (\beta \mu )}{\partial (\beta p)}}\right]_{\beta ,\lambda }d(\beta p)+\left[{\frac {\partial (\beta \mu )}{\partial \lambda }}\right]_{\beta ,\beta p}d\lambda .}$

Taking into account that ${\displaystyle \mu }$ is the Gibbs free energy per particle

${\displaystyle d\left(\beta \mu \right)={\frac {E}{N}}d\beta +{\frac {V}{N}}d(\beta p)+\left[{\frac {\partial (\beta \mu )}{\partial \lambda }}\right]_{\beta ,\beta p}d\lambda .}$

Let us use a bar to design quantities divided by the number of particles: e.g. ${\displaystyle {\bar {E}}=E/N;{\bar {V}}=V/N}$; and taking into account the definition:

${\displaystyle {\bar {L}}\equiv {\frac {1}{N}}\left[{\frac {\partial (\beta \mu )}{\partial \lambda }}\right]_{\beta ,\beta p}}$

Again, let us suppose that we have a phase coexistence at a point given by ${\displaystyle \left[\beta _{0},(\beta p)_{0},\lambda _{0}\right]}$ and that we want to modify slightly the conditions. In order to keep the system at the coexistence conditions:

${\displaystyle d\left[\beta \mu _{a}-\beta \mu _{b}\right]=0}$

Therefore, to keep the system on the coexistence conditions, the changes in the variables ${\displaystyle \beta ,(\beta p),\lambda }$ are constrained to fulfill:

${\displaystyle \left(\Delta {\bar {E}}\right)d\beta +\left(\Delta {\bar {V}}\right)d(\beta p)+\left(\Delta {\bar {L}}\right)d\lambda =0}$

whrere for any porperty ${\displaystyle X}$ we can define: ${\displaystyle \Delta X\equiv X_{a}-X_{b}}$ (i.e. the difference between the values of the property in the phases). Taking a path with, for instance constante ${\displaystyle \beta }$, the coexistence line will follow the trajectory produced by the solution of the differential equation:

${\displaystyle d(\beta p)=-{\frac {\Delta {\bar {L}}}{\Delta {\bar {V}}}}d\lambda .}$

TO BE CONTINUED

References

1. David A. Kofke, Gibbs-Duhem integration: a new method for direct evaluation of phase coexistence by molecular simulation, Mol. Phys. 78 , pp 1331 - 1336 (1993)
2. David A. Kofke, Direct evaluation of phase coexistence by molecular simulation via integration along the saturation line, J. Chem. Phys. 98 ,pp. 4149-4162 (1993)