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LAMMPS stands for Large-scale Atomic/Molecular Massively Parallel Simulator. LAMMPS has potentials for soft materials (biomolecules, polymers) and solid-state materials (metals, semiconductors) and coarse-grained or mesoscopic systems. It can be used to model atoms or, more generically, as a parallel particle simulator at the atomic, meso, or continuum scale.

Versions and Availability

Module Names for lammps on philip
Machine Version Module Name
None Available N/A N/A
▶ Module FAQ?

The information here is applicable to LSU HPC and LONI systems.


A user may choose between using /bin/bash and /bin/tcsh. Details about each shell follows.


System resource file: /etc/profile

When one access the shell, the following user files are read in if they exist (in order):

  1. ~/.bash_profile (anything sent to STDOUT or STDERR will cause things like rsync to break)
  2. ~/.bashrc (interactive login only)
  3. ~/.profile

When a user logs out of an interactive session, the file ~/.bash_logout is executed if it exists.

The default value of the environmental variable, PATH, is set automatically using SoftEnv. See below for more information.


The file ~/.cshrc is used to customize the user's environment if his login shell is /bin/tcsh.


Modules is a utility which helps users manage the complex business of setting up their shell environment in the face of potentially conflicting application versions and libraries.

Default Setup

When a user logs in, the system looks for a file named .modules in their home directory. This file contains module commands to set up the initial shell environment.

Viewing Available Modules

The command

$ module avail

displays a list of all the modules available. The list will look something like:

--- some stuff deleted ---

---------------- /usr/local/packages/Modules/modulefiles/admin -----------------
EasyBuild/1.11.1       GCC/4.9.0              INTEL-140-MPICH/3.1.1
EasyBuild/1.13.0       INTEL/14.0.2           INTEL-140-MVAPICH2/2.0
--- some stuff deleted ---

The module names take the form appname/version/compiler, providing the application name, the version, and information about how it was compiled (if needed).

Managing Modules

Besides avail, there are other basic module commands to use for manipulating the environment. These include:

add/load mod1 mod2 ... modn . . . Add modules
rm/unload mod1 mod2 ... modn  . . Remove modules
switch/swap mod . . . . . . . . . Switch or swap one module for another
display/show  . . . . . . . . . . List modules loaded in the environment
avail . . . . . . . . . . . . . . List available module names
whatis mod1 mod2 ... modn . . . . Describe listed modules

The -h option to module will list all available commands.

Module is currently available only on SuperMIC.


LAMMPS is normally run via a PBS batch script.

▶ Open Example?

Example PBS script for running LAMMPS. The value of ppn must match that allowed on the cluster of choice. The mpirun command must match that used by the version of MPI with which LAMMPS was compiled.

#PBS -A your_allocation
#PBS -q checkpt
#PBS -l nodes=1:ppn=8
#PBS -l walltime=12:00:00
#PBS -j oe
#PBS -N lammps-couette
export EXEC=lmp_linux
export EXEC_DIR=/usr/local/packages/lammps/4May11/intel-11.1-mvapich-1.1/bin
export NPROCS=`wc -l $PBS_NODEFILE |gawk '//{print $1}'`
mpirun -machinefile $PBS_NODEFILE -np $NPROCS $EXEC_DIR/$EXEC \
       < in.flow.couette 

The script is submitted via qsub.

▶ QSub FAQ?

Portable Batch System: qsub


All HPC@LSU clusters use the Portable Batch System (PBS) for production processing. Jobs are submitted to PBS using the qsub command. A PBS job file is basically a shell script which also contains directives for PBS.

$ qsub job_script

Where job_script is the name of the file containing the script.

PBS Directives

PBS directives take the form:

#PBS -X value

Where X is one of many single letter options, and value is the desired setting. All PBS directives must appear before any active shell statement.

Example Job Script
 # Use "workq" as the job queue, and specify the allocation code.
 #PBS -q workq
 #PBS -A your_allocation_code
 # Assuming you want to run 16 processes, and each node supports 4 processes, 
 # you need to ask for a total of 4 nodes. The number of processes per node 
 # will vary from machine to machine, so double-check that your have the right 
 # values before submitting the job.
 #PBS -l nodes=4:ppn=4
 # Set the maximum wall-clock time. In this case, 10 minutes.
 #PBS -l walltime=00:10:00
 # Specify the name of a file which will receive all standard output,
 # and merge standard error with standard output.
 #PBS -o /scratch/myName/parallel/output
 #PBS -j oe
 # Give the job a name so it can be easily tracked with qstat.
 #PBS -N MyParJob
 # That is it for PBS instructions. The rest of the file is a shell script.
 #   1. Copy the necessary files from your home directory to your scratch directory.
 #   2. Execute in your scratch directory.
 #   3. Copy any necessary files back to your home directory.

 # Let's mark the time things get started.


 # Set some handy environment variables.

 export HOME_DIR=/home/$USER/parallel
 export WORK_DIR=/scratch/myName/parallel
 # Set a variable that will be used to tell MPI how many processes will be run.
 # This makes sure MPI gets the same information provided to PBS above.

 export NPROCS=`wc -l $PBS_NODEFILE |gawk '//{print $1}'`

 # Copy the files, jump to WORK_DIR, and execute! The program is named "hydro".

 cp $HOME_DIR/hydro $WORK_DIR
 mpirun -machinefile $PBS_NODEFILE -np $NPROCS $WORK_DIR/hydro

 # Mark the time processing ends.

 # And we're out'a here!

 exit 0


Last modified: June 12 2015 16:24:59.