Intrinsic-reaction-coordinate calculations: Difference between revisions
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*{{TAG|IRC_VNORM0}} = 0.0020 | *{{TAG|IRC_VNORM0}} = 0.0020 | ||
{{NB|mind|This method is presently available only for fixed cell shape (i.e., | {{NB|mind|This method is presently available only for fixed cell shape (i.e., 2) simulations.}} | ||
{{NB|mind|This method is presently available only for fixed cell shape (i.e., {{TAG|ISIF}}=2).}} | {{NB|mind|This method is presently available only for fixed cell shape (i.e., {{TAG|ISIF}}=2).}} | ||
{{NB|mind|The calculation must be initialized from a very well relaxed transition state ({{TAG|EDIFFG}}=-0.005 or less in absolute value)}} | {{NB|mind|The calculation must be initialized from a very well relaxed transition state ({{TAG|EDIFFG}}=-0.005 or less in absolute value)}} |
Revision as of 11:04, 7 December 2022
The potential energy profiles along intrinsic reaction coordinate (IRC) can be computed via damped velocity Verlet algorithm of Hratchian and Schlegel[1].
- IRC_DIRECTION direction of the initial displacement (-1|1 – negative|positive)
- IRC_STOP = 20 the number of steps the energy must monotonously increase before the algorithm terminates. In order to avoid a premature terminations, especially close to transition states., e.g., due to a numerical noise, IRC_STOP should always be greater than 1.
- IRC_DELTA0 = 0.0015 the desired error – the smaller value, the closer the computed trajectory follows the true IRC (but the more DFT steps is needed)
- IRC_MINSTEP = 0.0250
- IRC_MAXSTEP = 3.0000
- IRC_VNORM0 = 0.0020
Mind: This method is presently available only for fixed cell shape (i.e., 2) simulations. |
Mind: {{{2}}} |
Mind: {{{2}}} |