Divergence of NEB calculation
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Divergence of NEB calculation
I tested twice a straightforward example of the chemical reaction
2 C2H4 ---> C4H8
with different INCARs
Here is my first divergent INCAR
SYSTEM = NEB
NCORE = 4
ISTART = 0
ICHARG = 2
ENCUT = 550.0
EDIFF = 0.1E-02
NSW = 250
IBRION = 1
ISIF = 2
ISYM = 1
POTIM = 0.5000
ISMEAR = -5
IALGO = 38
LWAVE = .FALSE.
LCHARG = .FALSE.
LVTOT = .FALSE.
SPRING = -5
IMAGES = 4
And my second (qusai?-)convergent INCAR, because of NSW(?), it just calculated one loop
So the result of it is reasonable quite well, compared to a result of activation graph which I saw in another tutorial
SYSTEM = NEB
NCORE = 4
ISTART = 0
ICHARG = 2
ENCUT = 550.0
EDIFF = 0.1E-02
NSW = 0 <-------------------- only different this
IBRION = 1
ISIF = 2
ISYM = 1
POTIM = 0.5000
ISMEAR = -5
IALGO = 38
LWAVE = .FALSE.
LCHARG = .FALSE.
LVTOT = .FALSE.
SPRING = -5
IMAGES = 4
When I run with 1st INCAR, it showed very divergent CONTCAR images at the end.
Even though I set EDIFF as 0.1E-02, it couldn't converge. (Maybe this is the INCAR problem, not the VTST and NEB?)
I want to get the more precise value less than 0.1E-05 or 0.1E-06 of EDIFF.
What should I change inside INCAR or what do I have to do?
And I'm searching for the tutorials on NEB calculation, but most browsers might be out of date.
If you know any tutorials or advice, could you let me know them?
2 C2H4 ---> C4H8
with different INCARs
Here is my first divergent INCAR
SYSTEM = NEB
NCORE = 4
ISTART = 0
ICHARG = 2
ENCUT = 550.0
EDIFF = 0.1E-02
NSW = 250
IBRION = 1
ISIF = 2
ISYM = 1
POTIM = 0.5000
ISMEAR = -5
IALGO = 38
LWAVE = .FALSE.
LCHARG = .FALSE.
LVTOT = .FALSE.
SPRING = -5
IMAGES = 4
And my second (qusai?-)convergent INCAR, because of NSW(?), it just calculated one loop
So the result of it is reasonable quite well, compared to a result of activation graph which I saw in another tutorial
SYSTEM = NEB
NCORE = 4
ISTART = 0
ICHARG = 2
ENCUT = 550.0
EDIFF = 0.1E-02
NSW = 0 <-------------------- only different this
IBRION = 1
ISIF = 2
ISYM = 1
POTIM = 0.5000
ISMEAR = -5
IALGO = 38
LWAVE = .FALSE.
LCHARG = .FALSE.
LVTOT = .FALSE.
SPRING = -5
IMAGES = 4
When I run with 1st INCAR, it showed very divergent CONTCAR images at the end.
Even though I set EDIFF as 0.1E-02, it couldn't converge. (Maybe this is the INCAR problem, not the VTST and NEB?)
I want to get the more precise value less than 0.1E-05 or 0.1E-06 of EDIFF.
What should I change inside INCAR or what do I have to do?
And I'm searching for the tutorials on NEB calculation, but most browsers might be out of date.
If you know any tutorials or advice, could you let me know them?
Last edited by nokimann on Sun Sep 16, 2018 4:41 pm, edited 1 time in total.
Re: Divergence of NEB calculation
I read a few posts. They mostly said "adjust POTIM and IBRION."
But I want to know how I can decide the value of POTIM and IBRION for all cases?
Does personal experience just govern it?
But I want to know how I can decide the value of POTIM and IBRION for all cases?
Does personal experience just govern it?
Re: Divergence of NEB calculation
There is some art to optimization, but there are also some sensible guidelines. When forces are high, use a conservative optimizer such as IBRION=3 and a small time step < 0.1. Once the forces are below 0.2 eV/Ang, you can switch to a second order optimizer (e.g. IBRION=1).
Re: Divergence of NEB calculation
You said 'forces,' but what did you mean by 'forces'?
+ How can I check that and before or after the NEB calculation?
And 'small time step' means the TIME-tag?
+ How can I check that and before or after the NEB calculation?
And 'small time step' means the TIME-tag?
Re: Divergence of NEB calculation
You can see the current NEB forces using our script nebef.pl.
The time step is controlled by POTIM is you use the built-in vasp-optimizers and by the TIMESTEP tag if you use our vtst optimizers.
The time step is controlled by POTIM is you use the built-in vasp-optimizers and by the TIMESTEP tag if you use our vtst optimizers.
Re: Divergence of NEB calculation
I'm still suffering from the divergence.
I guessed the reason is that the two C2H4 want to be separated from one another until all C2H4 has the same distance, considering the adjacent cells.
And, then I expand the cell size to lower the interaction between nearest cells, but it takes too long time to finish up.
In other words, it's difficult to check the results.
Do you have any advice?...
Note 1: When I tried just 'relaxation' steps, it was convergent indeed. Troubles only happened on IMAGE folders.
Note 2: The force value is small (0.01~0.02)
I guessed the reason is that the two C2H4 want to be separated from one another until all C2H4 has the same distance, considering the adjacent cells.
And, then I expand the cell size to lower the interaction between nearest cells, but it takes too long time to finish up.
In other words, it's difficult to check the results.
Do you have any advice?...
Note 1: When I tried just 'relaxation' steps, it was convergent indeed. Troubles only happened on IMAGE folders.
Note 2: The force value is small (0.01~0.02)
Re: Divergence of NEB calculation
If you can post a .tar.gz file of the calculation, I can provide more specific comments.
You can remove any large CHG* and WAV* files.
You can remove any large CHG* and WAV* files.
Re: Divergence of NEB calculation
Preparing the example for you.
By the way, I wonder the difference between inserting OUTCARs into 00 and 04 (if IMAGES = 4) folders and not.
By the way, I wonder the difference between inserting OUTCARs into 00 and 04 (if IMAGES = 4) folders and not.
Re: Divergence of NEB calculation
If you include OUTCAR files in the endpoint directories, our script will read them to get the endpoint energies, for example when minimum energy paths are plotted.
Re: Divergence of NEB calculation
I've prepared four calculations.
0_NEB is the 1st one, and 3_NEB is the last one.
Below is the description of what I did.
0_NEB: the first initial and final trial POSCAR, POTIM=0.01
not convergent for the calculation
images seem to be divergent. (See each CONTCAR in the image folder)
1_NEB: the initial trial POSCAR shifted from 0_NEB to have nearly equilibrium intervals between C2H4s
not convergent for the calculation
images seem to be divergent
2_NEB: POTIM increased as 0.1
convergent for the calculation
but the result images (CONTCARs) seem to be divergent
3_NEB: POTIM increased more as 0.25
not convergent both the calculation and the images
0_NEB is the 1st one, and 3_NEB is the last one.
Below is the description of what I did.
0_NEB: the first initial and final trial POSCAR, POTIM=0.01
not convergent for the calculation
images seem to be divergent. (See each CONTCAR in the image folder)
1_NEB: the initial trial POSCAR shifted from 0_NEB to have nearly equilibrium intervals between C2H4s
not convergent for the calculation
images seem to be divergent
2_NEB: POTIM increased as 0.1
convergent for the calculation
but the result images (CONTCARs) seem to be divergent
3_NEB: POTIM increased more as 0.25
not convergent both the calculation and the images
- Attachments
-
- NEB.tar.gz
- (377.61 MiB) Downloaded 2020 times
Re: Divergence of NEB calculation
A few points.
- make sure that you relax with a force criterion (ediffg < 0)
-- the relaxed endpoints are quite different in the attached path because of this
- when you have problems converging, use IBRION =3 and a small POTIM - all of you calculations used second order optimizers with unstable parameters
- Since the reactant molecules moved apart in the initial state, I needed more images to resolve the path
- turn of symmetry; you can see that the optimized path has broken the symmetry of the molecules. You would not be able to see this with symmetry turned on.
- start with low cutoffs for finding minimum energy pathways; it is easy to reconverge a path with more accurate setting when you have it.
- There is no need for any k-point sampling with isolated molecules; use the gamma point and a gamma point vasp binary.
- make sure that you relax with a force criterion (ediffg < 0)
-- the relaxed endpoints are quite different in the attached path because of this
- when you have problems converging, use IBRION =3 and a small POTIM - all of you calculations used second order optimizers with unstable parameters
- Since the reactant molecules moved apart in the initial state, I needed more images to resolve the path
- turn of symmetry; you can see that the optimized path has broken the symmetry of the molecules. You would not be able to see this with symmetry turned on.
- start with low cutoffs for finding minimum energy pathways; it is easy to reconverge a path with more accurate setting when you have it.
- There is no need for any k-point sampling with isolated molecules; use the gamma point and a gamma point vasp binary.
- Attachments
-
- 0_NEB.tar.gz
- (8.07 MiB) Downloaded 1577 times
Re: Divergence of NEB calculation
These are your comments. And I added queries for each comment.
- Make sure that you relax with a force criterion (EDIFFG < 0)
-- The relaxed endpoints are quite different in the attached path because of this
I searched the meaning of this Tag, and it means "If EDIFFG is negative it has a different meaning: In this case the relaxation
will stop if all forces are smaller than | EDIFFG |."
And force is defined by ionic positions, wavefunctions, and partial occupancies, isn't it?
Anyway, what I'm wondering is where all forces come from and how we can check?
I found the info. like the line below. So this line indicates the forces?
POSITION TOTAL-FORCE (eV/Angst)
If EDIFFG > 0, this means it stops when the change in ionic step is smaller than this Tag.
- When you have problems converging, use IBRION =3, and a small POTIM - all of you calculations used second-order optimizers with unstable parameters
I misunderstood about this. Checking the forces should be conducted on the results of NEB, not after relaxation, shouldn't it?
- Since the reactant molecules moved apart in the initial state, I needed more images to resolve the path
Ok.
- Turn off symmetry; you can see that the optimized path has broken the symmetry of the molecules. You would not be able to see this with symmetry turned on.
I tried it and also tried it with changing IALGO from 48 to 38. It gave me much faster convergent. What do you think about this?
And it has nearly symmetric results in CONTCAR. I might be caused by the smaller SC-loops compared to IALGO=48?
- Start with low cutoffs for finding minimum energy pathways; it is easy to reconverge a path with more accurate setting when you have it.
I've seen that ENCUT is usually x1.3~1.5 to the highest ENMAX in POTCARs. And it mostly guarantees the convergence in relaxation steps.
But you said 'low cutoffs.' Can you explain about this in NEB if you can?
- There is no need for any k-point sampling with isolated molecules; use the gamma point and a gamma point vasp binary.
I selected k-point as 'G' with 2 2 1. Did you mean by other things?
------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
Really happy for your advice. And it really works well. But I need time to understand your INCAR Tags.
- Make sure that you relax with a force criterion (EDIFFG < 0)
-- The relaxed endpoints are quite different in the attached path because of this
I searched the meaning of this Tag, and it means "If EDIFFG is negative it has a different meaning: In this case the relaxation
will stop if all forces are smaller than | EDIFFG |."
And force is defined by ionic positions, wavefunctions, and partial occupancies, isn't it?
Anyway, what I'm wondering is where all forces come from and how we can check?
I found the info. like the line below. So this line indicates the forces?
POSITION TOTAL-FORCE (eV/Angst)
If EDIFFG > 0, this means it stops when the change in ionic step is smaller than this Tag.
- When you have problems converging, use IBRION =3, and a small POTIM - all of you calculations used second-order optimizers with unstable parameters
I misunderstood about this. Checking the forces should be conducted on the results of NEB, not after relaxation, shouldn't it?
- Since the reactant molecules moved apart in the initial state, I needed more images to resolve the path
Ok.
- Turn off symmetry; you can see that the optimized path has broken the symmetry of the molecules. You would not be able to see this with symmetry turned on.
I tried it and also tried it with changing IALGO from 48 to 38. It gave me much faster convergent. What do you think about this?
And it has nearly symmetric results in CONTCAR. I might be caused by the smaller SC-loops compared to IALGO=48?
- Start with low cutoffs for finding minimum energy pathways; it is easy to reconverge a path with more accurate setting when you have it.
I've seen that ENCUT is usually x1.3~1.5 to the highest ENMAX in POTCARs. And it mostly guarantees the convergence in relaxation steps.
But you said 'low cutoffs.' Can you explain about this in NEB if you can?
- There is no need for any k-point sampling with isolated molecules; use the gamma point and a gamma point vasp binary.
I selected k-point as 'G' with 2 2 1. Did you mean by other things?
------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
Really happy for your advice. And it really works well. But I need time to understand your INCAR Tags.
Re: Divergence of NEB calculation
Yes, EDIFFG<0 is a force criterion - you should always use this.
Using symmetry for a symmetric structure will be fast, but as you can see from my calculation, the lowest energy path breaks that symmetry. Very few NEB calculations will have symmetry - just turn it off for these calculations.
In terms of the cutoff and all other parameters, start with inexpensive parameters when searching the potential landscape and finding transition states. Once you have found the reaction mechanisms, it is easy to reconverge with more accurate parameters and check for convergence.
For an isolated molecule you only need the gamma point (1 1 1) and you can also run a gamma point version of vasp which should increase the speed by about a factor of 2.
Using symmetry for a symmetric structure will be fast, but as you can see from my calculation, the lowest energy path breaks that symmetry. Very few NEB calculations will have symmetry - just turn it off for these calculations.
In terms of the cutoff and all other parameters, start with inexpensive parameters when searching the potential landscape and finding transition states. Once you have found the reaction mechanisms, it is easy to reconverge with more accurate parameters and check for convergence.
For an isolated molecule you only need the gamma point (1 1 1) and you can also run a gamma point version of vasp which should increase the speed by about a factor of 2.
Re: Divergence of NEB calculation
Thank you, professor.