ADF: Difference between revisions
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===Examples=== <!--T:26--> | ===Examples=== <!--T:26--> | ||
Example input/output for ADF can be found on Graham under | Example input/output for ADF can be found on Graham under | ||
/home/jemmyhu/tests/test_ADF/ | /home/jemmyhu/tests/test_ADF/2019.305/test_adf/ | ||
<!--T:28--> | <!--T:28--> | ||
The same procedure applies to BAND jobs, see band_test.inp and band_test.sh examples under | The same procedure applies to BAND jobs, see band_test.inp and band_test.sh examples under | ||
/home/jemmyhu/tests/test_ADF/ | /home/jemmyhu/tests/test_ADF/2019.305/test_band | ||
==Running SCM-GUI== <!--T:30--> | ==Running SCM-GUI== <!--T:30--> | ||
Revision as of 16:29, 4 September 2020
Introduction
The SCM (Software for Chemistry and Materials) Amsterdam Modeling Suite originally the ADF (Amsterdam Density Functional) Modeling Suite, offers powerful computational chemistry tools for many research areas such as homogeneous and heterogeneous catalysis, inorganic chemistry, heavy element chemistry, various types of spectroscopy, and biochemistry.
Compute Canada users have access to the following products:
- ADF
- ADF-GUI
- BAND
- BAND-GUI
- DFTB
- ReaxFF
- COSMO-RS
- QE-GUI
- NBO6
Running SCM on Graham
The adf module is installed only on Graham due to license restrictions. To check what versions are available use the module spider command as follows:
[name@server $] module spider adf
For module commands, please see Using modules.
Job submission
Graham uses the Slurm scheduler; for details about submitting jobs, see Running jobs.
Single ADF or BAND run
This mysub.sh script is for a whole-node job. The last two lines load version 2017.207 and call ADF directly.
#!/bin/bash
#SBATCH --nodes=1 --ntasks-per-node=32 # 1 node with 32 cpus, you can modify it
#SBATCH --mem=0 # request all memory on node
#SBATCH --time=00-03:00 # time (DD-HH:MM)
#SBATCH --output=adf_test-%j.log # output file
module load adf/2019.305
ADF adf_test.inp
This is the input file used in the script:
Title WATER Geometry Optimization with Delocalized Coordinates
Atoms
O 0.000000 0.000000 0.000000
H 0.000000 -0.689440 -0.578509
H 0.000000 0.689440 -0.578509
End
Basis
Type TZP
Core Small
End
Geometry
Optim Deloc
Converge 0.0000001
End
End Input
Multiple ADF or BAND runs
Multiple calculations can be combined into a single job by creating a input file such as this:
#!/bin/bash
if test -z "$SCM_TESTOUTPUT" ; then SCM_TESTOUTPUT=GO_H2O.out; fi
$ADFBIN/adf << eor > $SCM_TESTOUTPUT
Title WATER Geometry Optimization with Delocalized Coordinates
Atoms
O 0.000000 0.000000 0.000000
H 0.000000 -0.689440 -0.578509
H 0.000000 0.689440 -0.578509
End
Basis
Type TZP
Core Small
End
Geometry
Optim Deloc
Converge 0.0000001
End
End Input
eor
rm TAPE21 logfile
$ADFBIN/adf << eor >> $SCM_TESTOUTPUT
Title WATER Geometry Optimization in Cartesians with new optimizer
Atoms
O 0.000000 0.000000 0.000000
H 0.000000 -0.689440 -0.578509
H 0.000000 0.689440 -0.578509
End
Basis
Type TZP
Core Small
End
Geometry
Optim Cartesian
Branch New
Converge 0.0000001
End
End Input
eor
rm TAPE21 logfile
$ADFBIN/adf << eor >> $SCM_TESTOUTPUT
Title WATER Geometry Optimization with Internal Coordinates
Atoms Z-Matrix
1. O 0 0 0
2. H 1 0 0 rOH
3. H 1 2 0 rOH theta
End
Basis
Type TZP
Core Small
End
GeoVar
rOH=0.9
theta=100
End
Geometry
Converge 0.0000001
End
End Input
eor
rm TAPE21 logfile
$ADFBIN/adf << eor >> $SCM_TESTOUTPUT
Title WATER optimization with (partial) specification of Hessian
Atoms Z-Matrix
1. O 0 0 0
2. H 1 0 0 rOH
3. H 1 2 0 rOH theta
End
GeoVar
rOH=0.9
theta=100
End
HessDiag rad=1.0 ang=0.1
Fragments
H t21.H
O t21.O
End
Geometry
Converge 0.0000001
End
End Input
eor
rm TAPE21 logfile
$ADFBIN/adf << eor >> $SCM_TESTOUTPUT
Title WATER Geometry Optimization in Cartesians
Geometry
Optim Cartesian
Converge 0.0000001
End
Define
rOH=0.9
theta=100
End
Atoms Z-Matrix
1. O 0 0 0
2. H 1 0 0 rOH
3. H 1 2 0 rOH theta
End
Fragments
H t21.H
O t21.O
End
End Input
eor
mv TAPE21 H2O.t21
The following slurm script is identical to the one used for a single run (mysub.sh), except the last line calls the GO_H2O.run script, instead of ADF.
#!/bin/bash
#SBATCH --nodes=1 --ntasks-per-node=32 # 1 node with 32 cpus, you can modify it
#SBATCH --mem=0 # request all memory on node
#SBATCH --time=00-03:00 # time (DD-HH:MM)
#SBATCH --output=GO_H2O_%j.log # output file
module load adf/2019.305
bash GO_H2O.run # run the shell script
Examples
Example input/output for ADF can be found on Graham under
/home/jemmyhu/tests/test_ADF/2019.305/test_adf/
The same procedure applies to BAND jobs, see band_test.inp and band_test.sh examples under
/home/jemmyhu/tests/test_ADF/2019.305/test_band
Running SCM-GUI
Rendering over an SSH connection with X11 forwarding is very slow for GUI applications such as ADF-GUI. We recommend you use VNC to connect if you will be running ADF-GUI.
Graham
ADF can be run interactively in graphical mode on a Graham compute node (3hr time limit) over TigerVNC with these steps:
- Install a TigerVNC client on your desktop
- Connect to a compute node with vncviewer
module load adfadfinput
Gra-vdi
Adf can be run interactively in graphical mode on gra-vdi (no connection time limit) over TigerVNC with these steps:
- Install a TigerVNC client on your desktop
- Connect to gra-vdi.computecanada.ca with vncviewer
module load SnEnvmodule load clumodmodule load adfadfinput
A tutorial pdf showing how to install, connect and run ADF-GUI using TigerVNC on gra-vdi can be found here.
Locally
SCM has a separate license to run ADF-GUI on a local desktop machine. If you are interested contact license@scm.com to purchase your own license.