Difference between revisions of "Tutorial:Wires and slabs"
m (→Introduction) 

Line 3:  Line 3:  
== Introduction ==  == Introduction ==  
−  In the [[Tutorial:Periodic systemsPeriodic systems]] tutorial, we saw that the {{variablePeriodicDimensionsSystem}} input variable controls the number of dimensions to be considered as periodic. In that tutorial we only considered the case <tt>{{variablePeriodicDimensionsSystem}} = 3</tt>.  +  In the [[Tutorial:Periodic systemsPeriodic systems]] tutorial, we saw that the {{variablePeriodicDimensionsSystem}} input variable controls the number of dimensions to be considered as periodic. In that tutorial we only considered the case <tt>{{variablePeriodicDimensionsSystem}} = 3</tt>. Let's now see in detail the different cases: 
* <tt>{{variablePeriodicDimensionsSystem}} = 0</tt> (which is the default) gives a finite system calculation, since Dirichlet zero boundary conditions are used at all the borders of the simulation box;  * <tt>{{variablePeriodicDimensionsSystem}} = 0</tt> (which is the default) gives a finite system calculation, since Dirichlet zero boundary conditions are used at all the borders of the simulation box; 
Revision as of 21:20, 24 January 2019
In this tutorial we will explain how to use the flexibility of the realspace grid to treat systems that are periodic in only one or two dimensions. As examples we will use a Na chain and a hexagonal boron nitride (hBN) monolayer.
Contents
Introduction
In the Periodic systems tutorial, we saw that the PeriodicDimensions
input variable controls the number of dimensions to be considered as periodic. In that tutorial we only considered the case PeriodicDimensions
= 3. Let's now see in detail the different cases:

PeriodicDimensions
= 0 (which is the default) gives a finite system calculation, since Dirichlet zero boundary conditions are used at all the borders of the simulation box;

PeriodicDimensions
= 1 means that only the x axis is periodic, while in all the other directions the system is confined. This value must be used to simulate, for instance, a single infinite wire.

PeriodicDimensions
= 2 means that both x and y axis are periodic, while zero boundary conditions are imposed at the borders crossed by the z axis. This value must be used to simulate, for instance, a single infinite slab.

PeriodicDimensions
= 3 means that the simulation box is a primitive cell for a fully periodic infinite crystal. Periodic boundary conditions are imposed at all borders.
It is important to understand that performing, for instance, a PeriodicDimensions
= 1 calculation in Octopus is not quite the same as performing a PeriodicDimensions
= 3 calculation with a large supercell. In the infinitesupercell limit the two approaches reach the same ground state, but this does not hold for the excited states of the system.
Another point worth noting is how the Hartree potential is calculated for periodic systems. In fact the discrete Fourier transform that are used internally in a periodic calculation would always result in a 3D periodic lattice of identical replicas of the simulation box, even if only one or two dimensions are periodic. Fortunately Octopus includes a clever system to exactly truncate the longrange part of the Coulomb interaction, in such a way that we can effectively suppress the interactions between replicas of the system along nonperiodic axes ^{[1]}. This is done automatically, since the value of PoissonSolver
in a periodic calculation is chosen according to PeriodicDimensions
. See also the variable documentation for PoissonSolver
.
Sodium chain
Let us now calculate some bands for a simple single Na chain (i.e. not a crystal of infinite parallel chains, but just a single infinite chain confined in the other two dimensions).
Groundstate
First we start we the groundstate calculation using the following input file:
CalculationMode
= gsUnitsOutput
= ev_angstromExperimentalFeatures
= yesPeriodicDimensions
= 1Spacing
= 0.3*angstrom %Lsize
1.99932905*angstrom  5.29*angstrom  5.29*angstrom % %Coordinates
"Na"  0.0  0.0  0.0 % %KPointsGrid
9  1  1 %KPointsUseSymmetries
= yes
Most of these input variables were already introduced in the Periodic systems tutorial. Just note that the kpoints are all along the first dimension, as that is the only periodic dimension.
The output should be quite familiar, but the following piece of output confirms that the code is indeed using a cutoff for the calculation of the Hartree potential, as mentioned in the Introduction:
****************************** Hartree ******************************* The chosen Poisson solver is 'fast Fourier transform' Input: [PoissonFFTKernel = cylindrical] ********************************************************************** Input: [FFTLibrary = fftw] Info: FFT grid dimensions = 13 x 75 x 75 Total grid size = 73125 ( 0.6 MiB ) Inefficient FFT grid. A better grid would be: 14 75 75 Info: Poisson Cutoff Radius = 11.2 A
The cutoff used is a cylindrical cutoff and, by comparing the FFT grid dimensions with the size of the simulation box, we see that the Poisson solver is using a supercell doubled in size in the y and z directions.
At this point you might want to play around with the number of kpoints until you are sure the calculation is converged.
Band structure
We now modify the input file in the following way:
CalculationMode
= unoccUnitsOutput
= ev_angstromExperimentalFeatures
= yesPeriodicDimensions
= 1Spacing
= 0.3*angstrom %Lsize
1.99932905*angstrom  5.29*angstrom  5.29*angstrom % %Coordinates
"Na"  0.0  0.0  0.0 %ExtraStates
= 6ExtraStatesToConverge
= 4 %KPointsPath
14 0.0  0.0  0.0 0.5  0.0  0.0 %KPointsUseSymmetries
= no
and run the code. You might notice the comments on the the LCAO in the output. What's going on? Why can't a full initialization with LCAO be done?
You can now plot the band structure using the data from the static/bandstructure file, just like in the Periodic systems tutorial.
In the introduction we mentioned that performing a calculation with PeriodicDimensions
= 1 is not quite the same as performing a PeriodicDimensions
= 3 calculation with a large supercell. Lets now check this. Rerun both the groundstate and the unoccupied calculations, but setting PeriodicDimensions
= 3 in the above input files. Before doing so, make sure you copy the static/bandstructure file to a different place so that it is not overwritten (better yet, run the new calculations in a different folder). You can see the plot of the two band structures on the right. More comments on this in ref. ^{[1]}.
hBN monolayer
Hexagonal boron nitride (hBN) is an insulator widely studied which has a similar structure to graphene. Here we will describe how to get the band structure of an hBN monolayer.
Groundstate calculation
We will start by calculating the groundstate using the following input file:
CalculationMode
= gsUnitsOutput
= ev_angstromExperimentalFeatures
= yesPeriodicDimensions
= 2Spacing
= 0.20*angstrom BNlength = 1.445*angstrom a = sqrt(3)*BNlength L = 40 %LatticeParameters
a  a  L % %LatticeVectors
1.0  0.0  0.0 1/2  sqrt(3)/2  0.0 0.0  0.0  1.0 % %ReducedCoordinates
'B'  0.0  0.0  0.0 'N'  1/3  2/3  0.0 %PseudopotentialSet
=hgh_ldaLCAOStart
=lcao_states %KPointsGrid
12  12  1 %KPointsUseSymmetries
= yes
Most of the file should be selfexplanatory, but here is a more detailed explanation for some of the choices:

PeriodicDimensions
= 2: A layer of hBN is periodic in the xy directions, but not in the z direction, so there are two periodic dimensions.

LatticeParameters
: Here we have set the bond length to 1.445 Å. The box size in the z direction is 2 L with L large enough to describe a monolayer in the vacuum. Remember that one should always check the convergence of any quantities of interest with the box length value.
If you now run the code, you will notice that the cutoff used for the calculation of the Hartree potential is different than for the Sodium chain, as is to be expected:
****************************** Hartree ******************************* The chosen Poisson solver is 'fast Fourier transform' Input: [PoissonFFTKernel = planar] ********************************************************************** Input: [FFTLibrary = fftw] Info: FFT grid dimensions = 13 x 13 x 225 Total grid size = 38025 ( 0.3 MiB ) Inefficient FFT grid. A better grid would be: 14 14 225 Info: Poisson Cutoff Radius = 22.5 A
Band Structure
After the groundstate calculation, we will now calculate the band structure. This is the input for the nonself consistent calculation:
CalculationMode
= gsUnitsOutput
= ev_angstromExperimentalFeatures
= yesPeriodicDimensions
= 2Spacing
= 0.20*angstrom BNlength = 1.445*angstrom a = sqrt(3)*BNlength L = 40 %LatticeParameters
a  a  L % %LatticeVectors
1.0  0.0  0.0 1/2  sqrt(3)/2  0.0 0.0  0.0  1.0 % %ReducedCoordinates
'B'  0.0  0.0  0.0 'N'  1/3  2/3  0.0 %PseudopotentialSet
=hgh_ldaLCAOStart
=lcao_statesExtraStatesToConverge
= 4ExtraStates
= 8 %KPointsPath
12  7  12 # Number of k point to sample each path 0.0  0.0  0.0 # Reduced coordinate of the 'Gamma' k point 1/3  1/3  0.0 # Reduced coordinate of the 'K' k point 1/2  0.0  0.0 # Reduced coordinate of the 'M' k point 0.0  0.0  0.0 # Reduced coordinate of the 'Gamma' k point %KPointsUseSymmetries
= no
In this case, we chose the following path to calculate the band structure: GammaK, KM, MGamma, with a sampling of 12712 kpoints.
On the right is the resulting plot of the occupied bands and the first four unoccupied bands from the static/bandstructure file.
References
 ↑ ^{1.0} ^{1.1} C. A. Rozzi, D. Varsano, A. Marini, E. K. U. Gross, and A. Rubio, Exact Coulomb cutoff technique for supercell calculations, Phys. Rev. B 73 205119 (2006)