Category:Dielectric properties: Difference between revisions
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====ALGO = TDHF==== | ====ALGO = TDHF==== | ||
Time-dependent | This option performs a [[Bethe-Salpeter-equations calculations#Time-dependent Hartree-Fock calculation|time-dependent Hartree-Fock]] or [[Bethe-Salpeter-equations calculations#Time-dependent DFT calculation|DFT]] calculation. It follows the Casida equation and uses a Fourier transform of the time-evolving dipoles to compute <math>\epsilon</math>. | ||
The number of {{TAG|NBANDS}} controls how many bands are present in the time-evolution. This does not need to be as high as when {{TAG|LOPTICS}} is active, and only a few bands above the band gap need to be included. | |||
The choice of time-dependent kernel is controlled by {{TAG|AEXX}}, {{TAG|HFSCREEN}}, and {{TAG|LFXC}} variables. For calculations using hybrid functionals, {{TAG|AEXX}} controls the fraction of exact exchange used in the exchange correlation potential, while {{TAG|HFSCREEN}} specifies the range-separation parameter. For a pure TDDFT calculation, {{TAG|LFXC}} uses the local exchange-correlation kernel in the time-evolution equations. | |||
====ALGO = TIMEEV==== | ====ALGO = TIMEEV==== |
Revision as of 13:29, 18 October 2023
Introduction
Optics - response to a varying E-field (absorption, reflectance, MOKE)
Methods based on screened interaction in solids (MBPT)
Most general definition of epsilon D=epsilon E
Methods for computing
Static response: Density functional perturbation Theory (DFPT) and Finite differences based methods
LEPSILON
By setting LEPSILON=.True., VASP uses DFPT to compute the static ion-clamped dielectric matrix with or without local field effects. Derivatives are evaluated using Sternheimer equations, avoiding the explicit computation of derivatives of the periodic part of the wave function. This method does not require the inclusion of empty states via the NBANDS parameter.
At the end of the calculation the both the values of including (LRPA=.True.) or excluding (LRPA=.False.) local-field effects are printed in the OUTCAR file. Users can perform a consistency check by comparing the values with no local field to the zero frequency results for obtained from a calculation with LOPTICS=.True..
LCALCEPS
With LCALCEPS=.True., the dielectric tensor is computed from the derivative of the polarization, using
However, here the derivative is evaluated explicitly by employing finite-differences. The direction and intensity of the perturbing electric field has to be specified in the INCAR using the EFIELD_PEAD variable. As with the previous method, at the end of the calculation VASP will write the dielectric tensor in the OUTCAR file. Control over the inclusion of local-field effects is done with the variable LRPA.
Dynamical response
LOPITCS
The variable LOPTICS allows for the calculation of the frequency dependent dielectric function once the ground state is computed. It uses the explicit expression to evaluate the imaginary part of
while the real part is evaluated using the Kramers-Kroning relation. At this level there are no effects coming from local fields.
This method requires a relatively large number of empty states, controlled by the variable NBANDS in the INCAR and should be checked for convergence.
Furthermore, the INCAR should also include values for CSHIFT (the broadening applied to the Lorentzian function which replaces the -function), and NEDOS (the frequency grid for ).
ALGO = TDHF
This option performs a time-dependent Hartree-Fock or DFT calculation. It follows the Casida equation and uses a Fourier transform of the time-evolving dipoles to compute .
The number of NBANDS controls how many bands are present in the time-evolution. This does not need to be as high as when LOPTICS is active, and only a few bands above the band gap need to be included.
The choice of time-dependent kernel is controlled by AEXX, HFSCREEN, and LFXC variables. For calculations using hybrid functionals, AEXX controls the fraction of exact exchange used in the exchange correlation potential, while HFSCREEN specifies the range-separation parameter. For a pure TDDFT calculation, LFXC uses the local exchange-correlation kernel in the time-evolution equations.
ALGO = TIMEEV
Uses a delta-pulse to probe all transitions with a time-evolution equation. FT the dipoles also gives you epsilon
ALGO = CHI
ALGO = BSE
Setting ALGO=BSE computes the macroscopic dielectric function by solving the Bethe-Salpeter equations. Here the electron-hole pairs are treated a new quasi-particle, an exciton, and the dielectric function is built using the new eigenvectors () and eigenvalues ()
where is the overlap between exciton states of indices and (in general the BSE Hamiltonian is not hermitian, so eigenstates associated to different eigenvalues are not necessarily orthogonal).
The number of valence and conduction states which are included in the BSE Hamiltonian is controlled by the variables NBANDSO and NBANDSV, respectively. Note that normally only a few bands above and below the band gap are needed to converge the optical spectrum, so users should be careful in setting up these two variables. Otherwise the calculation might run out of memory.
For comparison with optical experiments (e.g. absorption, MOKE, reflectance), is the photon momentum and usually it is taken in the limit. Furthermore, the coupling between the resonant and anti-resonant terms can be switched off, in what is called the Tamm-Dancoff approximation. This approximation can be activated with the variable ANTIRES set to 0. Setting this variable to 1 or 2 will include the coupling, but increase the computational cost.
Level of approximation
Micro-macro connection - Including local fields (GG' vs GG or 00, to confirm)
Inhomogeniety - Long wavelength vs short
Local fields in the Hamiltonian
Ion-clamped vs relaxed/dressed dielectric function
Static vs dynamic
Density-density versus current-current response functions
Relation to observables
Polarizability
Optical conductivity
Optical absorption
Reflectance
MOKE
Combination with other perturbations
Atomic displacements
Strain
Pages in category "Dielectric properties"
The following 27 pages are in this category, out of 27 total.