Nucleophile Substitution CH3Cl - Standard MD
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
The main task of this example is to model a nucleophilic substitution of CH
Input
POSCAR
CH3Cl
1.00000000000000
12.0000000000000000 0.0000000000000000 0.0000000000000000
0.0000000000000000 12.0000000000000000 0.0000000000000000
0.0000000000000000 0.0000000000000000 12.0000000000000000
C H Cl
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
A sufficiently large cell is chosen to minimize the interactions between neighbouring cells and hence to simulate an isolated molecular reaction.
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=0.0258 ############################# MD setting ##################################### IBRION=0 # MD simulation NSW=1000 # number of steps POTIM=1 # integration step TEBEG=300 # simulation temperature MDALGO=11 # metaDynamics with Andersen thermostat ANDERSEN_PROB=0.10 # collision probability ##############################################################################
ICONST
For this example an ICONST file is used
R 1 5 0 R 1 6 0 S 1 -1 7