LPEAD: Difference between revisions
No edit summary |
No edit summary |
||
Line 56: | Line 56: | ||
[[Berry_phases_and_finite_electric_fields|Berry phases and finite electric fields]] | [[Berry_phases_and_finite_electric_fields|Berry phases and finite electric fields]] | ||
{{sc|LPEAD|Examples|Examples that use this tag}} | |||
{{ | |||
---- | ---- | ||
[[The_VASP_Manual|Contents]] | [[The_VASP_Manual|Contents]] | ||
[[Category:INCAR]][[Category:Berry phases]] | [[Category:INCAR]][[Category:Berry phases]] |
Revision as of 10:21, 20 March 2017
LPEAD = .TRUE. | .FALSE
Default: LPEAD = .FALSE.
Description: for LPEAD=.TRUE., the derivative of the cell-periodic part of the orbitals w.r.t. k, |∇kunk⟩, is calculated using finite differences.
The derivative of the cell-periodic part of the orbitals w.r.t. k, k, |∇kunk⟩, may be written as:
where H(k) and S(k) are the Hamiltonian and overlap operator for the cell-periodic part of the orbitals, and the sum over n´ must include a sufficiently large number of unoccupied states.
It may also be found as the solution to the following linear Sternheimer equation (see LEPSILON):
Alternatively one may compute from finite differences:
where m runs over the N occupied bands of the system, Δk=kj+1-kj, and
- .
As mentioned in the context of the self-consistent response to finite electric fields one may derive analoguous expressions for |∇kunk⟩ using higher-order finite difference approximations.
When LPEAD=.TRUE., VASP will compute |∇kunk⟩ using the aforementioned finite difference scheme. The order of the finite difference approximation can be specified by means of the IPEAD-tag (default: IPEAD=4).
These tags may be used in combination with LOPTICS=.TRUE. and LEPSILON=.TRUE..
Related Tags and Sections
IPEAD, LEPSILON, LOPTICS, LCALCEPS, EFIELD_PEAD, Berry phases and finite electric fields