Thermodynamic integration with harmonic reference: Difference between revisions
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Free energy of harmonic reference system within the quasi-classical theory writes | Free energy of harmonic reference system within the quasi-classical theory writes | ||
:<math> | :<math> | ||
A_{0,\ | A_{0,\mathbf{x}} = A_\mathrm{el}(\mathbf{x}_0) - k_\mathrm{B} T \sum_{i = 1}^{N_\mathrm{vib}} \ln \frac{k_\mathrm{B} T}{\hbar \omega_i} | ||
</math> | </math> | ||
with the electronic free energy <math>A_\mathrm{el}(\ | with the electronic free energy <math>A_\mathrm{el}(\mathbf{x}_0)</math> for the | ||
configuration corresponding to the potential energy minimum with the | configuration corresponding to the potential energy minimum with the | ||
atomic position vector <math>\ | atomic position vector <math>\mathbf{x}_0</math>, | ||
the number of vibrational degrees of freedom <math>N_\mathrm{vib}</math>, and the angular frequency $\omega_i$ of vibrational mode <math>i</math>. | the number of vibrational degrees of freedom <math>N_\mathrm{vib}</math>, and the angular frequency $\omega_i$ of vibrational mode <math>i</math>. |
Revision as of 07:52, 1 November 2023
The Helmholtz free energy () of a fully interacting system (1) can be expressed in terms of that of harmonic system (0) as follows
where is anharmonic free energy. The latter term can be determined by means of thermodynamic integration (TI)
with being the potential energy of system , is a coupling constant and is the NVT ensemble average of the system driven by the Hamiltonian
Free energy of harmonic reference system within the quasi-classical theory writes
with the electronic free energy for the configuration corresponding to the potential energy minimum with the atomic position vector , the number of vibrational degrees of freedom , and the angular frequency $\omega_i$ of vibrational mode .