AMS: Difference between revisions
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The full SCM module products are available: | |||
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==Running AMS on Graham== <!--T:6--> | ==Running AMS on Graham== <!--T:6--> | ||
The <code>ams</code> module is installed on [[Graham]] only due to license restrictions. To check what versions are available use the <code>module spider</code> command as follows: | The <code>ams</code> module is installed on [[Graham]] only due to license restrictions. To check what versions are available, use the <code>module spider</code> command as follows: | ||
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Graham uses the Slurm scheduler; for details about submitting jobs, see [[Running jobs]]. | Graham uses the Slurm scheduler; for details about submitting jobs, see [[Running jobs]]. | ||
====Example scripts for | ====Example scripts for an adf job ==== <!--T:16--> | ||
This H2O_adf.sh script is for a whole-node job. | This H2O_adf.sh script is for a whole-node job. | ||
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Revision as of 18:46, 23 June 2022
Introduction[edit]
AMS (Amsterdam Modeling Suite), originally named ADF (Amsterdam Density Functional), is the SCM Software for Chemistry and Materials. AMS 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.
The full SCM module products are available:
- ADF
- ADF-GUI
- BAND
- BAND-GUI
- DFTB
- ReaxFF
- COSMO-RS
- QE-GUI
- NBO6
Running AMS on Graham[edit]
The ams
module is installed on Graham only due to license restrictions. To check what versions are available, use the module spider
command as follows:
[name@server $] module spider ams
For module commands, please see Using modules.
Job submission[edit]
Graham uses the Slurm scheduler; for details about submitting jobs, see Running jobs.
Example scripts for an adf job[edit]
This H2O_adf.sh script is for a whole-node job.
#!/bin/bash
#SBATCH --account=def-pi
#SBATCH --nodes=1
#SBATCH --ntasks-per-node=32 # 1 node with all 32 cpus, MPI job
#SBATCH --mem=0 # request all memory on node
#SBATCH --time=00-01:00 # time (DD-HH:MM)
#SBATCH --output=H2O_adf-%j.log # output .log file
module unload openmpi
module load ams/2020.102
bash H2O_adf.run # run the input script
This is the input file used in the script:
#!/bin/sh
# This is a shell script for AMS2020
# You should use '$AMSBIN/ams' instead of '$ADFBIN/adf'
AMS_JOBNAME=H2O_adf $AMSBIN/ams <<eor
# Input options for the AMS driver:
System
Atoms
O 0.000000 0.000000 0.000000
H 0.000000 -0.689440 -0.578509
H 0.000000 0.689440 -0.578509
End
End
Task GeometryOptimization
GeometryOptimization
Convergence gradients=1e-4
End
# The input options for ADF, which are described in this manual,
# should be specified in the 'Engine ADF' block:
Engine ADF
Basis
Type TZP
End
XC
GGA PBE
End
EndEngine
eor
Example scripts for a band job[edit]
#!/bin/sh
# The calculation of the electric field gradient is invoked by the EFG key block
# Since Sn is quite an heavy atom we use the scalar relativistic option.
$AMSBIN/ams <<eor
Task SinglePoint
System
FractionalCoords True
Lattice
3.8029 0.0 0.0
0.0 3.8029 0.0
0.0 0.0 4.8382
End
Atoms
O 0.0 0.0 0.0
O 0.5 0.5 0.0
Sn 0.0 0.5 0.2369
Sn 0.5 0.0 -0.2369
End
End
Engine Band
Title SnO EFG
NumericalQuality Basic ! Only for speed
Tails bas=1e-8 ! Only for reproducibility with nr. of cores
! useful for Moessbauer spectroscopy: density and coulomb pot. at nuclei
PropertiesAtNuclei
End
EFG
Enabled True
End
Basis
Type DZ
Core none
End
EndEngine
eor
The following slurm script is similar to the one used for a single adf run (H2O_adf.sh), except it's not a whole-node job.
#!/bin/bash
#SBATCH --account=def-pi
#SBATCH --nodes=1
#SBATCH --ntasks-per-node=16 # a 16 cpus MPI job
#SBATCH --mem-per-cpu=3G # memory; 3G per cpu in this example
#SBATCH --time=00-10:00 # time (DD-HH:MM)
#SBATCH --output=SnO_EFG_band-%j.log
module unload openmpi
module load ams/2020.102
bash SnO_EFG_band.run # run the input file
Notes[edit]
- The input for AMS is different from ADF, the previous ADF input file will not run for the new AMS. Some examples can be found in /opt/software/ams/2020.102/examples/
- Except the output .log file, other files are all saved in a subdirectory AMS_JOBNAME.results. If AMS_JOBNAME is not defined in the input .run file, the default name is ams.results
- The restart file name is ams.rkf instead of the TAPE13 in previous ADF versions.
- You can watch a recorded webinar/tutorial: An Update on ADF/AMS software on Graham
For more usage information, please check the manuals in SCM Support
Running AMS-GUI[edit]
Rendering over an SSH connection with X11 forwarding is very slow for GUI applications such as AMS-GUI. We recommend you use VNC to connect if you will be running AMS-GUI.
Graham[edit]
AMS 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 ams
amsinput
Gra-vdi[edit]
AMS 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 SnEnv
module load clumod
module load ams
amsinput