Hybrid functionals
The objective of this tutorial is to give a basic idea of how to perform Hartree-Fock, as well as hybrid functionals calculations within the framework of generalized Kohn-Sham calculation.
Input
As always, we will start with a simple input file. In this example, we will look at the example of solid argon, treated using the HSE06 functional.
CalculationMode = gs
PeriodicDimensions = 3
BoxShape = parallelepiped
ExperimentalFeatures = yes
FromScratch = yes
PseudopotentialSet = sg15
a = 5.256*Angstrom
Spacing = 0.5
%LatticeParameters
a | a | a
%
%LatticeVectors
0. | 0.5 | 0.5
0.5 | 0. | 0.5
0.5 | 0.5 | 0.0
%
%ReducedCoordinates
"Ar" | 0.0 | 0.0 | 0.0
%
nk = 6
%KPointsGrid
nk | nk | nk
%
KPointsUseSymmetries = yes
ExtraStates = 1
ExperimentalFeatures = yes
XCFunctional = hyb_gga_xc_hse06
AdaptivelyCompressedExchange = yes
Let us look at the different input variable. Most of them have already been described in the Periodic System tutorials. What we have added here are:
- XCFunctional = hyb_gga_xc_hse06: This specifies that we are using the HSE06 exchange-correlation functional. This implies that the code will work in the generalized Kohn-Sham framework, which allows for nonlocal operators. If we would like to work in the usual Kohn-Sham framework, we would need to use the Optimized Effective Potential (OEP) method.
- AdaptivelyCompressedExchange = yes: This activates the use of the Adaptively Compressed Exchange (ACE) operator proposed in 1, which makes the evaluation of the exchange operator much faster.
Output
Now run Octopus using the above input file. Here are some important things to note from the output. First of all, we see that the theory level has been automatically switched to generalized_kohn_sham, and that the code is rightly using the requested HSE06 functional.
**************************** Theory Level ****************************
Input: [TheoryLevel = generalized_kohn_sham]
Exchange-correlation:
Exchange
Exact exchange
Exchange-correlation
HSE06 (Hybrid GGA)
[1] J. Heyd, G. E. Scuseria, and M. Ernzerhof., J. Chem. Phys. 118, 8207 (2003)
[2] J. Heyd, G. E. Scuseria, and M. Ernzerhof., J. Chem. Phys. 124, 219906 (2006)
[3] A. V. Krukau, O. A. Vydrov, A. F. Izmaylov, and G. E. Scuseria., J. Chem. Phys. 125, 224106 (2006)
Exact exchange mixing = 0.00000
Exact exchange for short-range beta = 0.25000
Exact exchange range-separate omega = 0.11000
**********************************************************************
The rest of the output is quite standard. As one main effect of using the HSE06 functional is to open the bandgap of solid argon. Indeed, looking at the static/info file, we see that we obtain a bandgap of roughly 10.3 eV:
Direct gap at ik= 1 of 0.3791 H
Indirect gap between ik= 1 and ik= 1 of 0.3791 H
whereas a similar PBE calculation produces a bandgap of only 8.6eV.
Hartree-Fock
If we want to perform not an hybrid-functional calculation but an Hartree-Fock calculation, we simply need to replace the definition of the functional by the line
TheoryLevel = hartree_fock
Note that this result is not yet converged with respect to the k-points.
The ACE operator should still be used here to obtain the best performance. Using the same input file but for Hartree-Fock, we obtain the HF bandgap of solid argon, which is roughly of 15.9 eV:
Direct gap at ik= 1 of 0.5840 H
Indirect gap between ik= 1 and ik= 1 of 0.5840 H
Using the ACE operator for TD calculations
Here we want to mention an important aspect of the ACE operator for TD simulations. By construction, the ACE operator is only defined at convergence of an SCF loop. For TD calculations, this implies that one should perform a self-consistency at every step of a TD calculation. At the moment, this is only implemented for the ETRS propagator, and we strongly recommend to use the following lines for a TD calculation using the ACE operator (AdaptivelyCompressedExchange = yes):
TDPropagator = etrs
TDStepsWithSelfConsistency = all_steps
References
-
Lin Lin, Adaptively Compressed Exchange Operator, J. Chem. Theory Comput. 12 2242–2249 (2016); ↩︎