Category:Electronic occupancy: Difference between revisions

Latest revision as of 06:39, 20 October 2025

Within the PAW method there is the occupation [math]\displaystyle{ f_k }[/math] for the plane-wave part and the on-site occupation matrix [math]\displaystyle{ \rho }[/math] that characterize the electronic state. Below we list tags and sections that can be used to influence the occupation, besides the obvious influence of the specific structure and exchange-correlation effects.

Modeling excited states by constrained occupation calculations

The delta self-consistent field (ΔSCF) method provides a practical way to obtain neutral excitation energies within density functional theory (DFT) by explicitly constraining the electronic occupations of selected orbitals. In contrast to linear-response or many-body approaches, ΔSCF directly evaluates the total energy difference between ground and excited electronic configurations from self-consistent calculations. This approach connects closely to experimental observables such as the vertical absorption energy (VAE), vertical emission energy (VEE), and zero-phonon lines (ZPLs), which are key quantities in the optical spectroscopy of point defects in semiconductors and insulators ^[1].

[math]\displaystyle{ \Delta\mathrm{SCF} }[/math] calculations: example of zero-phonon line calculation of [math]\displaystyle{ \mathrm{NV}^- }[/math] center in diamond

Density-functional theory plus dynamical mean-field theory

Density-functional theory plus dynamical mean-field theory (DFT+DMFT)^[2] is a method that provides a more accurate treatment of strongly correlated materials compared to DFT+U. While DFT+U is computationally much more affordable, it incorporates a static correction for localized electron interactions. DFT+DMFT, on the other hand, goes further by treating these interactions dynamically, capturing frequency-dependent electron correlations. A key feature of DFT+DMFT is that the charge density is updated using the DMFT solution, ensuring a self-consistent feedback between the correlated electronic states and the DFT potential. This not only improves the description of phenomena like metal-insulator transitions and quasiparticle renormalization but also allows for the calculation of spectral properties such as photoemission spectra, transport properties, and total energies relevant to structural distortions. To facilitate DFT+DMFT calculations, VASP provides a general interface to DMFT codes, allowing occupation updates ICHARG=5 via an external file vaspgamma.h5 / GAMMA to update the charge density.

DFT+DMFT calculations: example of performing DFT+DMFT calculations using the TRIQS software^[3]

References

Pages in category "Electronic occupancy"

The following 16 pages are in this category, out of 16 total.

D

Delta self-consistent field

E

F

FERDO
FERWE

G

GAMMA

I

N

NELECT

P

PLUGINS/OCCUPANCIES

S

V

Vaspgamma.h5

Z

ZVAL

[Freysoldt2014-1] Christoph Freysoldt, Blazej Grabowski, Tilmann Hickel, Jörg Neugebauer, Georg Kresse, Anderson Janotti, Rev. Mod. Phys. (2014).

[kotliar:rmp:2006-2] G. Kotliar, S. Y. Savrasov, K. Haule, V. S. Oudovenko, O. Parcollet, and C. A. Marianetti, Electronic structure calculations with dynamical mean-field theory, Rev. Mod. Phys. 78, 865 (2006)

[parcollet:cpc:196-3] O. Parcollet, M. Ferrero, T. Ayral, H. Hafermann, I. Krivenko, L. Messio and P. Seth, Computer Physics Communications 196, 398 (2015).

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 Within the [[PAW method]] there is the occupation <math>f_k</math> for the plane-wave part and the on-site occupation matrix <math>\rho</math> that characterize the [[Electronic ground-state properties|electronic state]]. Below we list tags and sections that can be used to influence the occupation, besides the obvious influence of the specific [[Ionic minimization|structure]] and [[XC functional|exchange-correlation effects]].
-== Theory ==
+== Modeling excited states by constrained occupation calculations ==
-=== Density Functional Theory plus Dynamical Mean Field Theory ===
+The '''delta self-consistent field (ΔSCF)''' method provides a practical way to obtain neutral excitation energies within density functional theory (DFT) by explicitly constraining the electronic '''occupations''' of selected orbitals.
+In contrast to [[:Category:Linear_response|linear-response]] or [[:Category:Many-body perturbation theory|many-body approaches]], ΔSCF directly evaluates the total energy difference between ground and excited electronic configurations from self-consistent calculations.
+This approach connects closely to experimental observables such as the '''vertical absorption energy (VAE)''', '''vertical emission energy (VEE)''', and '''zero-phonon lines (ZPLs)''', which are key quantities in the [[:Category:Dielectric properties|optical spectroscopy]] of point defects in semiconductors and insulators {{cite|Freysoldt2014}}.
-Density Functional Theory plus Dynamical Mean Field Theory (DFT+DMFT){{cite|kotliar:rmp:2006}} is an advanced extension of DFT that provides a more accurate treatment of strongly correlated materials compared to [[:Category:DFT+U|DFT+U]]. While DFT+U incorporates a static correction for localized electron interactions, DFT+DMFT goes further by treating these interactions dynamically, capturing frequency-dependent electron correlations. A key feature of DFT+DMFT is that the charge density is updated using the DMFT solution, ensuring a self-consistent feedback between the correlated electronic states and the DFT potential. This not only improves the description of phenomena like metal-insulator transitions and quasiparticle renormalization but also allows for the calculation of spectral properties such as photoemission spectra, transport properties, and total energies relevant to structural distortions. To facilitate DFT+DMFT calculations, VASP provides a general interface to DMFT codes, allowing occupation updates {{TAG|ICHARG}}=5 via an external file {{FILE|vaspgamma.h5}} / {{FILE|GAMMA}} to update the charge density.
+*[[Delta self-consistent field|<math display="inline">\Delta\mathrm{SCF}</math> calculations]]: example of zero-phonon line calculation of <math display="inline">\mathrm{NV}^-</math> center in diamond
-== How to ==
+== Density-functional theory plus dynamical mean-field theory ==
-Practical guides to different methods manipulating occupations in VASP are found on following pages:
+'''Density-functional theory plus dynamical mean-field theory (DFT+DMFT)'''{{cite|kotliar:rmp:2006}} is a method that provides a more accurate treatment of '''strongly correlated materials''' compared to [[:Category:DFT+U|DFT+U]]. While [[:Category:DFT+U|DFT+U]] is computationally much more affordable, it incorporates a static correction for localized electron interactions. DFT+DMFT, on the other hand, goes further by treating these interactions dynamically, capturing frequency-dependent electron correlations. A key feature of DFT+DMFT is that the charge density is updated using the DMFT solution, ensuring a self-consistent feedback between the correlated electronic states and the DFT potential. This not only improves the description of phenomena like '''metal-insulator transitions''' and quasiparticle renormalization but also allows for the calculation of spectral properties such as '''photoemission spectra''', '''transport properties''', and '''total energies relevant to structural distortions'''. To facilitate DFT+DMFT calculations, VASP provides a general interface to DMFT codes, allowing occupation updates {{TAG|ICHARG}}=5 via an external file {{FILE|vaspgamma.h5}} / {{FILE|GAMMA}} to update the charge density.
 *{{TAG|DFT+DMFT calculations}}: example of performing DFT+DMFT calculations using the [https://triqs.github.io/triqs TRIQS software]{{cite|parcollet:cpc:196}}
-*[[Delta Self-Consistent Field|<math display="inline">\Delta\mathrm{SCF}</math> calculations]]: example of zero-phonon line calculation of <math display="inline">\mathrm{NV}^-</math> center in diamond
 == References ==