Thermodynamic integration with harmonic reference: Difference between revisions

Revision as of 07:46, 1 November 2023

The Helmholtz free energy ( $A$ ) of a fully interacting system (1) can be expressed in terms of that of harmonic system (0) as follows

A_{1}=A_{0}+\Delta A_{0\rightarrow 1}

where $\Delta A_{0\rightarrow 1}$ is anharmonic free energy. The latter term can be determined by means of thermodynamic integration

\Delta A_{0\rightarrow 1}=\int _{0}^{1}d\lambda \langle V_{1}-V_{0}\rangle _{\lambda }

with $V_{i}$ being the potential energy of system $i$ , $\lambda$ is a coupling constant and $\langle \cdots \rangle _{\lambda }$ is the NVT ensemble average of the system driven by the Hamiltonian

{\mathcal {H}}_{\lambda }=\lambda {\mathcal {H}}_{1}+(1-\lambda ){\mathcal {H}}_{0},

@@ Line 7: / Line 7: @@
 \Delta A_{0\rightarrow 1} = \int_0^1 d\lambda \langle V_1 -V_0  \rangle_\lambda
 </math>
-with <math>V_i</math> being the potential energy of system <math>i</math>, <math>\lambda</math> is a coupling constant and
+with <math>V_i</math> being the potential energy of system <math>i</math>, <math>\lambda</math> is a coupling constant and <math>\langle\cdots\rangle_\lambda</math> is the NVT ensemble average of the system driven by the Hamiltonian
+:<math>
+\mathcal{H}_\lambda = \lambda \mathcal{H}_1 + (1-\lambda)\mathcal{H}_0,
+</math>