Nuclephile Substitution CH3Cl - mMD2: Difference between revisions

Revision as of 15:39, 19 September 2019

Overview >Liquid Si - Standard MD > Liquid Si - Freezing > Nucleophile Substitution CH3Cl - Standard MD > Nuclephile Substitution CH3Cl - mMD1 > Nuclephile Substitution CH3Cl - mMD2 > Nuclephile Substitution CH3Cl - mMD3 > Nuclephile Substitution CH3Cl - SG > Nuclephile Substitution CH3Cl - BM > List of tutorials

Task

In this example the nucleophile substitution of a Cl^- by another Cl^- in CH₃Cl via meta dynamics is correctly simulated by using extra "repulsive potential walls."

Input

POSCAR

   1.00000000000000
     12.0000000000000000    0.0000000000000000    0.0000000000000000
     0.0000000000000000    12.0000000000000000    0.0000000000000000
     0.0000000000000000    0.0000000000000000    12.0000000000000000
   1   3   2
cart
         5.91331371  7.11364924  5.78037960
         5.81982231  8.15982106  5.46969017
         4.92222130  6.65954232  5.88978969
         6.47810398  7.03808479  6.71586385
         4.32824726  8.75151396  7.80743202
         6.84157897  6.18713289  4.46842049

KPOINTS

Automatic
 0
Gamma
 1  1  1
 0. 0. 0.

For isolated atoms and molecules interactions between periodic images are negligible (in sufficiently large cells) hence no Brillouin zone sampling is necessary.

INCAR

PREC=Low
EDIFF=1e-6
LWAVE=.FALSE.
LCHARG=.FALSE.
NELECT=22
NELMIN=4
LREAL=.FALSE.
ALGO=VeryFast
ISMEAR=-1
SIGMA=0.0516

############################# MD setting #####################################
IBRION=0                                           # MD simulation
NSW=1000                                           # number of steps
POTIM=1                                            # integration step
TEBEG=600                                          # simulation temperature
MDALGO=11                                          # metaDynamics with Andersen thermostat
ANDERSEN_PROB=0.10                                 # collision probability
HILLS_BIN=50                                       # update the time-dependent bias
                                                           # potential every 50 steps
HILLS_H=0.005                                      # height of the Gaussian
HILLS_W=0.05                                       # width of the Gaussian
##############################################################################

Same INCAR file as in the previous example (Nuclephile Substitution CH3Cl - mMD).

ICONST

R 1 5 0
R 1 6 0
S 1 -1 5

In principle, meta dynamics always seeks for the path of least resistance. In the case of our model system this corresponds to the dissociation of the vdW complex (which is linked with a lower barrier than the SN2 reaction). In order to avoid this undesired process, an extra bias potential ("repulsive walls") is used whose role is to restrict our sampling to a relevant region (approx. $-3 \AA <$ collective variable $< 3 A$ ). In fact, the positions of walls can be chosen arbitrarily - we only require that the region between the walls contains all the information we are interested in (in this case we want to see free-energy minima for both "reactant" and "product" as well as the "transition state"). In order for the walls to be effective, we also require that they are significantly higher than the expected reaction barrier (otherwise the likelihood to cross the wall during meta dynamics would be higher than that for the barrier). From the potential energy profile (static calculations not reported here) we obtained a reasonable guess for the reaction barrier - it is about 0.4 eV - hence the height for the wall of 1 eV should be sufficient.

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Overview >Liquid Si - Standard MD > Liquid Si - Freezing > Nucleophile Substitution CH3Cl - Standard MD > Nuclephile Substitution CH3Cl - mMD1 > Nuclephile Substitution CH3Cl - mMD2 > Nuclephile Substitution CH3Cl - mMD3 > Nuclephile Substitution CH3Cl - SG > Nuclephile Substitution CH3Cl - BM > List of tutorials

@@ Line 60: / Line 60: @@
   R 1 6 0
   S 1 -1 5
+== {{TAG|Calculation}} ==
+In principle, meta dynamics always seeks for the path of least resistance. In the case of our model system this corresponds to the dissociation of the vdW complex (which is linked with a lower barrier than the SN2 reaction). In order to avoid this undesired process, an extra bias potential ("repulsive walls") is used whose role is to restrict our sampling to a relevant region (approx. <math>-3 \AA < </math> collective variable <math>< 3 A</math>). In fact, the positions of walls can be chosen arbitrarily - we only require that the region between the walls contains all the information we are interested in (in this case we want to see free-energy minima for both "reactant" and "product" as well as the "transition state"). In order for the walls to be effective, we also require that they are significantly higher than the expected reaction barrier (otherwise the likelihood to cross the wall during meta dynamics would be higher than that for the barrier). From the potential energy profile (static calculations not reported here) we obtained a reasonable guess for the reaction barrier - it is about 0.4 eV - hence the height for the wall of 1 eV should be sufficient.