Category:Exchange-correlation functionals: Difference between revisions

Revision as of 13:48, 18 January 2022

In the Kohn-Sham (KS) formulation of density functional theory (DFT)^[1]^[2], the total energy is given by

{\displaystyle E_{\rm tot} = -\frac{1}{2}\sum_{i}\int\psi_{i}^{*}({\bf r})\nabla^{2}\psi_{i}({\bf r})d^{3}r - \sum_{A}\int\frac{Z_{A}}{\left\vert{\bf r}-{\bf R}_{A}\right\vert}\rho({\bf r})d^{3}r + \frac{1}{2}\int\int\frac{\rho({\bf r})\rho({\bf r'})}{\left\vert{\bf r}-{\bf r'}\right\vert}d^{3}rd^{3}r' + E_{\rm xc} + \frac{1}{2}\sum_{A\ne B}\frac{Z_{A}Z_{B}}{\left\vert{\bf R}_{A}-{\bf R}_{B}\right\vert} }

where the terms on the right-hand side represent the non-interacting kinetic energy of the electrons, the electrons-nuclei attraction energy, the classical Coulomb electron-electron repulsive energy, the exchange-correlation energy and the nuclei-nuclei repulsion energy. The orbitals $\psi_{i}$ and the electron density $\rho=\sum_{i}\left\vert\psi_{i}\right\vert^{2}$ that are used to evaluate $E_{\rm tot}$ are obtained by solving self-consistently the KS equations

{\displaystyle \left(-\frac{1}{2}\nabla^{2} -\sum_{A}\frac{Z_{A}}{\left\vert{\bf r}-{\bf R}_{A}\right\vert} + \int\frac{\rho({\bf r'})}{\left\vert{\bf r}-{\bf r'}\right\vert}d^{3}r' + v_{\rm xc}({\bf r})\right)\psi_{i}({\bf r}) = \epsilon_{i}\psi_{i}({\bf r}) }

The only terms in $E_{\rm tot}$ and in the KS equations that are not known exactly are the exchange-correlation energy $E_{\rm xc}$ and potential $v_{\rm xc}=\delta E_{\rm xc}/\delta\rho$ In the KS-DFT method. Therefore, the accuracy of the calculated properties depends mainly on the approximations used for $E_{\rm xc}$ and $v_{\rm xc}=\delta E_{\rm xc}/\delta\rho$ .

Theoretical Background

Hybrid functionals: Hartree-Fock and HF/DFT hybrid functionals.
L(S)DA (on-site interactions): LDAUTYPE.
van der Waals:

How to

Hybrid functionals: Specific hybrid functionals.
Meta GGA's: METAGGA.
L(S)DA (on-site interactions): LDAUTYPE.
van der Waals:
- Main tag for van der Waals algorithm: IVDW
- DFT-D2 method.
- DFT-D3 method.
- DDsC dispersion correction.
- Many-body dispersion energy.
- Tkatchenko-Scheffler method.
- Tkatchenko-Scheffler method with iterative Hirshfeld partitioning.
- Self-consistent screening in Tkatchenko-Scheffler method.
- VdW-DF functional of Langreth and Lundqvist et al.

Subcategories

This category has the following 5 subcategories, out of 5 total.

Pages in category "Exchange-correlation functionals"

The following 118 pages are in this category, out of 118 total.

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[hohenberg:pr:1964-1] P. Hohenberg and W. Kohn, Phys. Rev. 136, B864 (1964).

[kohn:pr:1965-2] W. Kohn and L. J. Sham, Phys. Rev. 140, A1133 (1965).

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@@ Line 8: / Line 8: @@
 \left(-\frac{1}{2}\nabla^{2} -\sum_{A}\frac{Z_{A}}{\left\vert{\bf r}-{\bf R}_{A}\right\vert} + \int\frac{\rho({\bf r'})}{\left\vert{\bf r}-{\bf r'}\right\vert}d^{3}r' + v_{\rm xc}({\bf r})\right)\psi_{i}({\bf r}) = \epsilon_{i}\psi_{i}({\bf r})
 </math>
-The only terms in <math>E_{\rm tot}</math> and in the KS equations that are not known exactly is the exchange-correlation energy <math>E_{\rm xc}</math> and potential <math>v_{\rm xc}=\delta E_{\rm xc}/\delta\rho</math>
+The only terms in <math>E_{\rm tot}</math> and in the KS equations that are not known exactly are the exchange-correlation energy <math>E_{\rm xc}</math> and potential <math>v_{\rm xc}=\delta E_{\rm xc}/\delta\rho</math>
 In the KS-DFT method. Therefore, the accuracy of the calculated properties depends mainly on the approximations used for <math>E_{\rm xc}</math> and <math>v_{\rm xc}=\delta E_{\rm xc}/\delta\rho</math>.