Fcc Si: Difference between revisions
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{{Template:Bulk_systems - Tutorial}} | |||
== Task == | |||
Lattice constant optimization for fcc Si. | |||
== Input == | |||
=== {{TAG|POSCAR}} === | |||
fcc Si: | fcc Si: | ||
3.9 | 3.9 | ||
Line 25: | Line 17: | ||
0 0 0 | 0 0 0 | ||
* | *Fcc Si lattice constant of 3.9 <math>\AA</math>. | ||
*1 atom per unit cell. | |||
=== {{TAG|INCAR}} === | |||
{{TAGBL|System}} = fcc Si | |||
{{TAGBL|ISTART}} = 0 ; {{TAGBL|ICHARG}} = 2 | |||
{{TAGBL|ENCUT}} = 240 | |||
{{TAGBL|ISMEAR}} = 0; {{TAGBL|SIGMA}} = 0.1 | |||
*Initial charge density form overlapping atoms. | |||
*Energy cutoff of 240 eV from {{TAG|POTCAR}} file. | |||
=== {{TAG|KPOINTS}} === | |||
k-points | |||
0 | |||
Monkhorst Pack | |||
11 11 11 | |||
0 0 0 | |||
*Equally spaced k mesh. | |||
*Odd number of k points in each direction results in a <math>\Gamma</math> centered mesh. | |||
*56 k points in IBZ. | |||
== Calculation == | |||
*Calculate energy for different lattice parameters. | |||
*Fit to some equation of states to obtain the equilibrium volume. | |||
*The bash-script <tt>loop.sh</tt> runs fcc Si at several different lattice constants (3.5-4.3 Å) and collects free energy versus lattice constant into the file SUMMARY.fcc | |||
<pre> | <pre> | ||
#! /bin/bash | #! /bin/bash | ||
Line 47: | Line 67: | ||
</pre> | </pre> | ||
The output for the SUMMARY.fcc file within this example should look like this: | |||
3.5 1 F= -.44256712E+01 E0= -.44233993E+01 d E =-.454388E-02 | |||
3.6 1 F= -.46614699E+01 E0= -.46600410E+01 d E =-.285796E-02 | |||
3.7 1 F= -.47979864E+01 E0= -.47959298E+01 d E =-.411323E-02 | |||
3.8 1 F= -.48645042E+01 E0= -.48630063E+01 d E =-.299564E-02 | |||
3.9 1 F= -.48773847E+01 E0= -.48758538E+01 d E =-.306176E-02 | |||
4.0 1 F= -.48487436E+01 E0= -.48481092E+01 d E =-.126878E-02 | |||
4.1 1 F= -.47852634E+01 E0= -.47844854E+01 d E =-.155599E-02 | |||
4.2 1 F= -.46936947E+01 E0= -.46922530E+01 d E =-.288339E-02 | |||
4.3 1 F= -.45831167E+01 E0= -.45811837E+01 d E =-.386598E-02 | |||
*To make a quick plot of SUMMARY.fcc try: | *To make a quick plot of SUMMARY.fcc try: | ||
Line 53: | Line 83: | ||
gnuplot | gnuplot | ||
gnuplot> plot "SUMMARY.fcc" using ($1):($4) w lp | gnuplot> plot "SUMMARY.fcc" using ($1):($4) w lp | ||
*The equilibrium lattice constant is found at roughly 3.9 Å. Adjust your {{TAG|POSCAR}} file to reflect this and rerun VASP. | |||
*Keep your {{TAG|CHGCAR}} file from this run. We will need it in the following examples. | |||
*A quick look at the results: | |||
[[File:Fig Si 1.png|800px]] | |||
'''Mind''': You will have to set the correct path to your VASP executable (i.e., <tt>BIN</tt>), and invoke VASP with the correct command (e.g., in the above: <tt>mpirun -np 2</tt>). | |||
== Download == | == Download == | ||
[ | [[Media:FccSi.tgz| fccSi.tgz]] | ||
{{Template:Bulk_systems}} | |||
[[Category:Examples]] | [[Category:Examples]] |
Latest revision as of 13:24, 14 November 2019
Overview > fcc Si > fcc Si DOS > fcc Si bandstructure > cd Si > cd Si volume relaxation > cd Si relaxation > beta-tin Si > fcc Ni > graphite TS binding energy > graphite MBD binding energy > graphite interlayer distance > List of tutorials
Task
Lattice constant optimization for fcc Si.
Input
POSCAR
fcc Si: 3.9 0.5 0.5 0.0 0.0 0.5 0.5 0.5 0.0 0.5 1 cartesian 0 0 0
- Fcc Si lattice constant of 3.9 .
- 1 atom per unit cell.
INCAR
System = fcc Si ISTART = 0 ; ICHARG = 2 ENCUT = 240 ISMEAR = 0; SIGMA = 0.1
- Initial charge density form overlapping atoms.
- Energy cutoff of 240 eV from POTCAR file.
KPOINTS
k-points 0 Monkhorst Pack 11 11 11 0 0 0
- Equally spaced k mesh.
- Odd number of k points in each direction results in a centered mesh.
- 56 k points in IBZ.
Calculation
- Calculate energy for different lattice parameters.
- Fit to some equation of states to obtain the equilibrium volume.
- The bash-script loop.sh runs fcc Si at several different lattice constants (3.5-4.3 Å) and collects free energy versus lattice constant into the file SUMMARY.fcc
#! /bin/bash BIN=/path/to/your/vasp/executable rm WAVECAR SUMMARY.fcc for i in 3.5 3.6 3.7 3.8 3.9 4.0 4.1 4.2 4.3 ; do cat >POSCAR <<! fcc: $i 0.5 0.5 0.0 0.0 0.5 0.5 0.5 0.0 0.5 1 cartesian 0 0 0 ! echo "a= $i" ; mpirun -np 2 $BIN E=`awk '/F=/ {print $0}' OSZICAR` ; echo $i $E >>SUMMARY.fcc done cat SUMMARY.fcc
The output for the SUMMARY.fcc file within this example should look like this:
3.5 1 F= -.44256712E+01 E0= -.44233993E+01 d E =-.454388E-02 3.6 1 F= -.46614699E+01 E0= -.46600410E+01 d E =-.285796E-02 3.7 1 F= -.47979864E+01 E0= -.47959298E+01 d E =-.411323E-02 3.8 1 F= -.48645042E+01 E0= -.48630063E+01 d E =-.299564E-02 3.9 1 F= -.48773847E+01 E0= -.48758538E+01 d E =-.306176E-02 4.0 1 F= -.48487436E+01 E0= -.48481092E+01 d E =-.126878E-02 4.1 1 F= -.47852634E+01 E0= -.47844854E+01 d E =-.155599E-02 4.2 1 F= -.46936947E+01 E0= -.46922530E+01 d E =-.288339E-02 4.3 1 F= -.45831167E+01 E0= -.45811837E+01 d E =-.386598E-02
- To make a quick plot of SUMMARY.fcc try:
gnuplot gnuplot> plot "SUMMARY.fcc" using ($1):($4) w lp
- The equilibrium lattice constant is found at roughly 3.9 Å. Adjust your POSCAR file to reflect this and rerun VASP.
- Keep your CHGCAR file from this run. We will need it in the following examples.
- A quick look at the results:
Mind: You will have to set the correct path to your VASP executable (i.e., BIN), and invoke VASP with the correct command (e.g., in the above: mpirun -np 2).