Calculation of dimers: Difference between revisions
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For this {{TAG|POSCAR}} file the starting distance is 2.56 <math>\AA</math>, in each step the distance is reduced by 0.04 <math>\AA</math>, leading to a final distance of 2.20 <math>\AA</math>. The obtained energies can be fitted to a Morse potential. | For this {{TAG|POSCAR}} file the starting distance is 2.56 <math>\AA</math>, in each step the distance is reduced by 0.04 <math>\AA</math>, leading to a final distance of 2.20 <math>\AA</math>. The obtained energies can be fitted to a Morse potential. | ||
Mind: In some rare cases like C<sub>2</sub>, the calculation of the dimer turns out to be problematic. For this case the LUMO (lowest unoccupied molecular orbital) and the HOMO (highest occupied molecular orbital) cross at a certain distance, and are actually degenerate, if the total energy is used as a variational quantity (i.e. <math>sigma \to 0</math>). Within the finite temperature LDA these difficulties are avoided, but interpreting the results is not easy because of the finite entropy (for C | Mind: In some rare cases like C<sub>2</sub>, the calculation of the dimer turns out to be problematic. For this case the LUMO (lowest unoccupied molecular orbital) and the HOMO (highest occupied molecular orbital) cross at a certain distance, and are actually degenerate, if the total energy is used as a variational quantity (i.e. <math>\sigma \to 0</math>). Within the finite temperature LDA these difficulties are avoided, but interpreting the results is not easy because of the finite entropy (for C<sub>2</sub> see Ref. {{cite|pederson:prb:1991}}). | ||
== References == | |||
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[[Category:Atoms and Molecules]][[Category:Howto]] | [[Category:Atoms and Molecules]][[Category:Howto]] |
Latest revision as of 06:03, 20 June 2022
Reproducing accurate dimer distances is an important difficult benchmark for a potential. If a potential works accurately for dimers and bulk calculations, one can be quite confident that the potential possesses excellent transferability. For the simulation of the dimers, one can use the point and displace the second atom along the diagonal direction. Generally bonding length and vibrational frequency have to be compared with accurate reference data. It is recommended to perform these calculations using the constant velocity molecular dynamic mode (i.e. IBRION=2, SMASS=-2). This mode speeds up the calculation because the wave functions are extrapolated and predicted using information from previous steps. The INCAR file must contain additional lines to perform the constant velocity MD:
#ionic relaxation NSW = 10 #number of steps for IOM SMASS = -2 #constant velocity MD POTIM = 1 #time-step for ionic-motion
In addition to the positions the POSCAR file must also contain velocities:
dimer 1 10.00000 .00000 .00000 .00000 10.00000 .00000 .00000 .00000 10.00000 2 cart 0 0 0 1.47802 1.47802 1.47802 cart 0 0 0 -.02309 -.02309 -.02309
For this POSCAR file the starting distance is 2.56 , in each step the distance is reduced by 0.04 , leading to a final distance of 2.20 . The obtained energies can be fitted to a Morse potential.
Mind: In some rare cases like C2, the calculation of the dimer turns out to be problematic. For this case the LUMO (lowest unoccupied molecular orbital) and the HOMO (highest occupied molecular orbital) cross at a certain distance, and are actually degenerate, if the total energy is used as a variational quantity (i.e. ). Within the finite temperature LDA these difficulties are avoided, but interpreting the results is not easy because of the finite entropy (for C2 see Ref. [1]).
References