At and mol further: Difference between revisions
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*How does the energy change when one decreases {{TAG|SIGMA}} to 0.001 in the {{TAG|INCAR}} file starting from the {{TAG|O_atom}}? Why? | *How does the energy change when one decreases {{TAG|SIGMA}} to 0.001 in the {{TAG|INCAR}} file starting from the {{TAG|O_atom}}? Why? |
Revision as of 13:19, 7 June 2019
Overview > O atom > O atom spinpolarized > O atom spinpolarized low symmetry > O dimer > CO > CO vibration > CO partial DOS > H2O >
H2O vibration > H2O molecular dynamics > Further things to try > List of tutorials
- How does the energy change when one decreases SIGMA to 0.001 in the INCAR file starting from the O_atom? Why?
- What is the reason for the imaginary frequency in the example CO_vibration? Does the behaviour improve when the step width (smaller or larger) is changed? Also try to improve the precision to which the ground state is converged (EDIFF=1E-5). What happens if the accuracy of the calculations is improved (PREC=Accurate}}).
- Try to use the conjugate gradient algorithm to the molecule (example H2O).
- Calculate the vibrational frequencies of the molecule (example H2O) after relaxation (example H2Ovib). Why does one find 3 modes that have small frequencies? Try EDIFF=1E-5 instead of EDIFF=1E-4.
Overview > O atom > O atom spinpolarized > O atom spinpolarized low symmetry > O dimer > CO > CO vibration > CO partial DOS > H2O >
H2O vibration > H2O molecular dynamics > Further things to try > List of tutorials
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