forked from lijiext/lammps
629 lines
28 KiB
Plaintext
629 lines
28 KiB
Plaintext
"Previous Section"_Manual.html - "LAMMPS WWW Site"_lws - "LAMMPS Documentation"_ld - "LAMMPS Commands"_lc - "Next Section"_Section_start.html :c
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:link(lws,http://lammps.sandia.gov)
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:link(ld,Manual.html)
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:link(lc,Section_commands.html#comm)
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:line
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1. Introduction :h3
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These sections provide an overview of what LAMMPS can and can't do,
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describe what it means for LAMMPS to be an open-source code, and
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acknowledge the funding and people who have contributed to LAMMPS over
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the years.
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1.1 "What is LAMMPS"_#intro_1
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1.2 "LAMMPS features"_#intro_2
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1.3 "LAMMPS non-features"_#intro_3
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1.4 "Open source distribution"_#intro_4
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1.5 "Acknowledgments and citations"_#intro_5 :all(b)
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:line
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1.1 What is LAMMPS :link(intro_1),h4
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LAMMPS is a classical molecular dynamics code that models an ensemble
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of particles in a liquid, solid, or gaseous state. It can model
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atomic, polymeric, biological, metallic, granular, and coarse-grained
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systems using a variety of force fields and boundary conditions.
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For examples of LAMMPS simulations, see the Publications page of the
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"LAMMPS WWW Site"_lws.
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LAMMPS runs efficiently on single-processor desktop or laptop
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machines, but is designed for parallel computers. It will run on any
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parallel machine that compiles C++ and supports the "MPI"_mpi
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message-passing library. This includes distributed- or shared-memory
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parallel machines and Beowulf-style clusters.
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:link(mpi,http://www-unix.mcs.anl.gov/mpi)
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LAMMPS can model systems with only a few particles up to millions or
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billions. See "this section"_Section_perf.html for information on LAMMPS
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performance and scalability, or the Benchmarks section of the "LAMMPS
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WWW Site"_lws.
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LAMMPS is a freely-available open-source code, distributed under the
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terms of the "GNU Public License"_gnu, which means you can use or
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modify the code however you wish. See "this section"_#intro_4 for a brief
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discussion of the open-source philosophy.
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:link(gnu,http://www.gnu.org/copyleft/gpl.html)
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LAMMPS is designed to be easy to modify or extend with new
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capabilities, such as new force fields, atom types, boundary
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conditions, or diagnostics. See "this section"_Section_modify.html for
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more details.
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The current version of LAMMPS is written in C++. Earlier versions
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were written in F77 and F90. See "this section"_Section_history.html
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for more information on different versions. All versions can be
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downloaded from the "LAMMPS WWW Site"_lws.
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LAMMPS was originally developed under a US Department of Energy CRADA
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(Cooperative Research and Development Agreement) between two DOE labs
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and 3 companies. It is distributed by "Sandia National Labs"_snl.
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See "this section"_#intro_5 for more information on LAMMPS funding and
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individuals who have contributed to LAMMPS.
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:link(snl,http://www.sandia.gov)
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In the most general sense, LAMMPS integrates Newton's equations of
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motion for collections of atoms, molecules, or macroscopic particles
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that interact via short- or long-range forces with a variety of
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initial and/or boundary conditions. For computational efficiency
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LAMMPS uses neighbor lists to keep track of nearby particles. The
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lists are optimized for systems with particles that are repulsive at
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short distances, so that the local density of particles never becomes
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too large. On parallel machines, LAMMPS uses spatial-decomposition
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techniques to partition the simulation domain into small 3d
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sub-domains, one of which is assigned to each processor. Processors
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communicate and store "ghost" atom information for atoms that border
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their sub-domain. LAMMPS is most efficient (in a parallel sense) for
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systems whose particles fill a 3d rectangular box with roughly uniform
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density. Papers with technical details of the algorithms used in
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LAMMPS are listed in "this section"_#intro_5.
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:line
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1.2 LAMMPS features :link(intro_2),h4
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This section highlights LAMMPS features, with pointers to specific
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commands which give more details. If LAMMPS doesn't have your
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favorite interatomic potential, boundary condition, or atom type, see
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"this section"_Section_modify.html, which describes how you can add it to
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LAMMPS.
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General features :h4
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runs on a single processor or in parallel
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distributed-memory message-passing parallelism (MPI)
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spatial-decomposition of simulation domain for parallelism
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open-source distribution
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highly portable C++
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optional libraries used: MPI and single-processor FFT
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easy to extend with new features and functionality
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runs from an input script
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syntax for defining and using variables and formulas
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syntax for looping over runs and breaking out of loops
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run one or multiple simulations simultaneously (in parallel) from one script
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build as library, invoke LAMMPS thru library interface or provided Python wrapper
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couple with other codes: LAMMPS calls other code, other code calls LAMMPS, umbrella code calls both :ul
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Particle and model types :h4
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("atom style"_atom_style.html command)
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atoms
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coarse-grained particles (e.g. bead-spring polymers)
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united-atom polymers or organic molecules
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all-atom polymers, organic molecules, proteins, DNA
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metals
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granular materials
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coarse-grained mesoscale models
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extended spherical and ellipsoidal particles
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point dipolar particles
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rigid collections of particles
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hybrid combinations of these :ul
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Force fields :h4
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("pair style"_pair_style.html, "bond style"_bond_style.html,
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"angle style"_angle_style.html, "dihedral style"_dihedral_style.html,
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"improper style"_improper_style.html, "kspace style"_kspace_style.html
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commands)
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pairwise potentials: Lennard-Jones, Buckingham, Morse, Born-Mayer-Huggins, \
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Yukawa, soft, class 2 (COMPASS), hydrogen bond, tabulated
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charged pairwise potentials: Coulombic, point-dipole
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manybody potentials: EAM, Finnis/Sinclair EAM, modified EAM (MEAM), \
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embedded ion method (EIM), ADP, Stillinger-Weber, Tersoff, REBO, AIREBO, ReaxFF, COMB
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electron force field (eFF, AWPMD)
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coarse-grained potentials: DPD, GayBerne, REsquared, colloidal, DLVO
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mesoscopic potentials: granular, Peridynamics, SPH
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bond potentials: harmonic, FENE, Morse, nonlinear, class 2, \
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quartic (breakable)
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angle potentials: harmonic, CHARMM, cosine, cosine/squared, cosine/periodic, \
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class 2 (COMPASS)
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dihedral potentials: harmonic, CHARMM, multi-harmonic, helix, \
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class 2 (COMPASS), OPLS
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improper potentials: harmonic, cvff, umbrella, class 2 (COMPASS)
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polymer potentials: all-atom, united-atom, bead-spring, breakable
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water potentials: TIP3P, TIP4P, SPC
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implicit solvent potentials: hydrodynamic lubrication, Debye
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long-range Coulombics and dispersion: Ewald, \
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PPPM (similar to particle-mesh Ewald), Ewald/N for long-range Lennard-Jones
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force-field compatibility with common CHARMM, AMBER, DREIDING, OPLS, GROMACS, COMPASS options
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handful of GPU-enabled pair styles :ul
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hybrid potentials: multiple pair, bond, angle, dihedral, improper \
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potentials can be used in one simulation
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overlaid potentials: superposition of multiple pair potentials
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Atom creation :h4
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("read_data"_read_data.html, "lattice"_lattice.html,
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"create_atoms"_create_atoms.html, "delete_atoms"_delete_atoms.html,
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"displace_atoms"_displace_atoms.html, "replicate"_replicate.html commands)
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read in atom coords from files
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create atoms on one or more lattices (e.g. grain boundaries)
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delete geometric or logical groups of atoms (e.g. voids)
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replicate existing atoms multiple times
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displace atoms :ul
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Ensembles, constraints, and boundary conditions :h4
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("fix"_fix.html command)
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2d or 3d systems
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orthogonal or non-orthogonal (triclinic symmetry) simulation domains
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constant NVE, NVT, NPT, NPH, Parinello/Rahman integrators
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thermostatting options for groups and geometric regions of atoms
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pressure control via Nose/Hoover or Berendsen barostatting in 1 to 3 dimensions
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simulation box deformation (tensile and shear)
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harmonic (umbrella) constraint forces
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rigid body constraints
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SHAKE bond and angle constraints
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bond breaking, formation, swapping
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walls of various kinds
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non-equilibrium molecular dynamics (NEMD)
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variety of additional boundary conditions and constraints :ul
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Integrators :h4
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("run"_run.html, "run_style"_run_style.html, "minimize"_minimize.html commands)
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velocity-Verlet integrator
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Brownian dynamics
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rigid body integration
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energy minimization via conjugate gradient or steepest descent relaxation
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rRESPA hierarchical timestepping :ul
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Diagnostics :h4
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see the various flavors of the "fix"_fix.html and "compute"_compute.html commands :ul
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Output :h4
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("dump"_dump.html, "restart"_restart.html commands)
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log file of thermodynamic info
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text dump files of atom coords, velocities, other per-atom quantities
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binary restart files
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parallel I/O of dump and restart files
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per-atom quantities (energy, stress, centro-symmetry parameter, CNA, etc)
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user-defined system-wide (log file) or per-atom (dump file) calculations
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spatial and time averaging of per-atom quantities
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time averaging of system-wide quantities
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atom snapshots in native, XYZ, XTC, DCD, CFG formats :ul
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Multi-replica models :h4
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"nudged elastic band"_neb.html
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"parallel replica dynamics"_prd.html
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"temperature accelerated dynamics"_tad.html
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"parallel tempering"_temper.html
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Pre- and post-processing :h4
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Various pre- and post-processing serial tools are packaged
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with LAMMPS; see these "doc pages"_Section_tools.html. :ulb,l
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Our group has also written and released a separate toolkit called
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"Pizza.py"_pizza which provides tools for doing setup, analysis,
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plotting, and visualization for LAMMPS simulations. Pizza.py is
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written in "Python"_python and is available for download from "the
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Pizza.py WWW site"_pizza. :l,ule
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:link(pizza,http://www.sandia.gov/~sjplimp/pizza.html)
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:link(python,http://www.python.org)
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Specialized features :h4
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These are LAMMPS capabilities which you may not think of as typical
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molecular dynamics options:
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"stochastic rotation dynamics (SRD)"_fix_srd.html
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"real-time visualization and interactive MD"_fix_imd.html
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"atom-to-continuum coupling"_fix_atc.html with finite elements
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coupled rigid body integration via the "POEMS"_fix_poems.html library
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"grand canonical Monte Carlo"_doc/fix_gcmc.html insertions/deletions
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"Direct Simulation Monte Carlo"_pair_dsmc.html for low-density fluids
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"Peridynamics mesoscale modeling"_pair_peri.html
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"targeted"_fix_tmd.html and "steered"_fix_smd.html molecular dynamics
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"two-temperature electron model"_fix_ttm.html :ul
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:line
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1.3 LAMMPS non-features :link(intro_3),h4
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LAMMPS is designed to efficiently compute Newton's equations of motion
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for a system of interacting particles. Many of the tools needed to
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pre- and post-process the data for such simulations are not included
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in the LAMMPS kernel for several reasons:
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the desire to keep LAMMPS simple
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they are not parallel operations
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other codes already do them
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limited development resources :ul
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Specifically, LAMMPS itself does not:
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run thru a GUI
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build molecular systems
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assign force-field coefficients automagically
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perform sophisticated analyses of your MD simulation
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visualize your MD simulation
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plot your output data :ul
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A few tools for pre- and post-processing tasks are provided as part of
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the LAMMPS package; they are described in "this
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section"_Section_tools.html. However, many people use other codes or
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write their own tools for these tasks.
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As noted above, our group has also written and released a separate
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toolkit called "Pizza.py"_pizza which addresses some of the listed
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bullets. It provides tools for doing setup, analysis, plotting, and
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visualization for LAMMPS simulations. Pizza.py is written in
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"Python"_python and is available for download from "the Pizza.py WWW
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site"_pizza.
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LAMMPS requires as input a list of initial atom coordinates and types,
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molecular topology information, and force-field coefficients assigned
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to all atoms and bonds. LAMMPS will not build molecular systems and
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assign force-field parameters for you.
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For atomic systems LAMMPS provides a "create_atoms"_create_atoms.html
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command which places atoms on solid-state lattices (fcc, bcc,
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user-defined, etc). Assigning small numbers of force field
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coefficients can be done via the "pair coeff"_pair_coeff.html, "bond
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coeff"_bond_coeff.html, "angle coeff"_angle_coeff.html, etc commands.
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For molecular systems or more complicated simulation geometries, users
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typically use another code as a builder and convert its output to
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LAMMPS input format, or write their own code to generate atom
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coordinate and molecular topology for LAMMPS to read in.
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For complicated molecular systems (e.g. a protein), a multitude of
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topology information and hundreds of force-field coefficients must
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typically be specified. We suggest you use a program like
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"CHARMM"_charmm or "AMBER"_amber or other molecular builders to setup
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such problems and dump its information to a file. You can then
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reformat the file as LAMMPS input. Some of the tools in "this
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section"_Section_tools.html can assist in this process.
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Similarly, LAMMPS creates output files in a simple format. Most users
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post-process these files with their own analysis tools or re-format
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them for input into other programs, including visualization packages.
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If you are convinced you need to compute something on-the-fly as
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LAMMPS runs, see "this section"_Section_modify.html for a discussion
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of how you can use the "dump"_dump.html and "compute"_compute.html and
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"fix"_fix.html commands to print out data of your choosing. Keep in
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mind that complicated computations can slow down the molecular
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dynamics timestepping, particularly if the computations are not
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parallel, so it is often better to leave such analysis to
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post-processing codes.
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A very simple (yet fast) visualizer is provided with the LAMMPS
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package - see the "xmovie"_Section_tools.html#xmovie tool in "this
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section"_Section_tools.html. It creates xyz projection views of
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atomic coordinates and animates them. We find it very useful for
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debugging purposes. For high-quality visualization we recommend the
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following packages:
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"VMD"_http://www.ks.uiuc.edu/Research/vmd
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"AtomEye"_http://mt.seas.upenn.edu/Archive/Graphics/A
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"PyMol"_http://pymol.sourceforge.net
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"Raster3d"_http://www.bmsc.washington.edu/raster3d/raster3d.html
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"RasMol"_http://www.openrasmol.org :ul
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Other features that LAMMPS does not yet (and may never) support are
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discussed in "this section"_Section_history.html.
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Finally, these are freely-available molecular dynamics codes, most of
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them parallel, which may be well-suited to the problems you want to
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model. They can also be used in conjunction with LAMMPS to perform
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complementary modeling tasks.
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"CHARMM"_charmm
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"AMBER"_amber
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"NAMD"_namd
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"NWCHEM"_nwchem
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"DL_POLY"_dlpoly
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"Tinker"_tinker :ul
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:link(charmm,http://www.scripps.edu/brooks)
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:link(amber,http://amber.scripps.edu)
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:link(namd,http://www.ks.uiuc.edu/Research/namd/)
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:link(nwchem,http://www.emsl.pnl.gov/docs/nwchem/nwchem.html)
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:link(dlpoly,http://www.cse.clrc.ac.uk/msi/software/DL_POLY)
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:link(tinker,http://dasher.wustl.edu/tinker)
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CHARMM, AMBER, NAMD, NWCHEM, and Tinker are designed primarily for
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modeling biological molecules. CHARMM and AMBER use
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atom-decomposition (replicated-data) strategies for parallelism; NAMD
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and NWCHEM use spatial-decomposition approaches, similar to LAMMPS.
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Tinker is a serial code. DL_POLY includes potentials for a variety of
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biological and non-biological materials; both a replicated-data and
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spatial-decomposition version exist.
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:line
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1.4 Open source distribution :link(intro_4),h4
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LAMMPS comes with no warranty of any kind. As each source file states
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in its header, it is a copyrighted code that is distributed free-of-
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charge, under the terms of the "GNU Public License"_gnu (GPL). This
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is often referred to as open-source distribution - see
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"www.gnu.org"_gnuorg or "www.opensource.org"_opensource for more
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details. The legal text of the GPL is in the LICENSE file that is
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included in the LAMMPS distribution.
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:link(gnuorg,http://www.gnu.org)
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:link(opensource,http://www.opensource.org)
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Here is a summary of what the GPL means for LAMMPS users:
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(1) Anyone is free to use, modify, or extend LAMMPS in any way they
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choose, including for commercial purposes.
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(2) If you distribute a modified version of LAMMPS, it must remain
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open-source, meaning you distribute it under the terms of the GPL.
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You should clearly annotate such a code as a derivative version of
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LAMMPS.
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(3) If you release any code that includes LAMMPS source code, then it
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must also be open-sourced, meaning you distribute it under the terms
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of the GPL.
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(4) If you give LAMMPS files to someone else, the GPL LICENSE file and
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source file headers (including the copyright and GPL notices) should
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remain part of the code.
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In the spirit of an open-source code, these are various ways you can
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contribute to making LAMMPS better. You can send email to the
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"developers"_http://lammps.sandia.gov/authors.html on any of these
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items.
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Point prospective users to the "LAMMPS WWW Site"_lws. Mention it in
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talks or link to it from your WWW site. :ulb,l
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If you find an error or omission in this manual or on the "LAMMPS WWW
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Site"_lws, or have a suggestion for something to clarify or include,
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send an email to the
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"developers"_http://lammps.sandia.gov/authors.html. :l
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If you find a bug, "this section"_Section_errors.html#err_2 describes
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how to report it. :l
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If you publish a paper using LAMMPS results, send the citation (and
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any cool pictures or movies if you like) to add to the Publications,
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Pictures, and Movies pages of the "LAMMPS WWW Site"_lws, with links
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and attributions back to you. :l
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Create a new Makefile.machine that can be added to the src/MAKE
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directory. :l
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The tools sub-directory of the LAMMPS distribution has various
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stand-alone codes for pre- and post-processing of LAMMPS data. More
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details are given in "this section"_Section_tools.html. If you write
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a new tool that users will find useful, it can be added to the LAMMPS
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distribution. :l
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LAMMPS is designed to be easy to extend with new code for features
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like potentials, boundary conditions, diagnostic computations, etc.
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"This section"_Section_modify.html gives details. If you add a
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feature of general interest, it can be added to the LAMMPS
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distribution. :l
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The Benchmark page of the "LAMMPS WWW Site"_lws lists LAMMPS
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performance on various platforms. The files needed to run the
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benchmarks are part of the LAMMPS distribution. If your machine is
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sufficiently different from those listed, your timing data can be
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added to the page. :l
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You can send feedback for the User Comments page of the "LAMMPS WWW
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Site"_lws. It might be added to the page. No promises. :l
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Cash. Small denominations, unmarked bills preferred. Paper sack OK.
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Leave on desk. VISA also accepted. Chocolate chip cookies
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encouraged. :ule,l
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:line
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1.5 Acknowledgments and citations :h4,link(intro_5)
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LAMMPS development has been funded by the "US Department of
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Energy"_doe (DOE), through its CRADA, LDRD, ASCI, and Genomes-to-Life
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programs and its "OASCR"_oascr and "OBER"_ober offices.
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Specifically, work on the latest version was funded in part by the US
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Department of Energy's Genomics:GTL program
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("www.doegenomestolife.org"_gtl) under the "project"_ourgtl, "Carbon
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Sequestration in Synechococcus Sp.: From Molecular Machines to
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Hierarchical Modeling".
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:link(doe,http://www.doe.gov)
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:link(gtl,http://www.doegenomestolife.org)
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:link(ourgtl,http://www.genomes2life.org)
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:link(oascr,http://www.sc.doe.gov/ascr/home.html)
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:link(ober,http://www.er.doe.gov/production/ober/ober_top.html)
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The following papers describe the parallel algorithms used in LAMMPS.
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S. J. Plimpton, [Fast Parallel Algorithms for Short-Range Molecular
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Dynamics], J Comp Phys, 117, 1-19 (1995).
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S. J. Plimpton, R. Pollock, M. Stevens, [Particle-Mesh Ewald and
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rRESPA for Parallel Molecular Dynamics Simulations], in Proc of the
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Eighth SIAM Conference on Parallel Processing for Scientific
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Computing, Minneapolis, MN (March 1997).
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If you use LAMMPS results in your published work, please cite the J
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Comp Phys reference and include a pointer to the "LAMMPS WWW Site"_lws
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(http://lammps.sandia.gov).
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If you send is information about your publication, we'll be pleased to
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add it to the Publications page of the "LAMMPS WWW Site"_lws. Ditto
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for a picture or movie for the Pictures or Movies pages.
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The core group of LAMMPS developers is at Sandia National Labs. They
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include "Steve Plimpton"_sjp, Paul Crozier, and Aidan Thompson and can
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be contacted via email: sjplimp, pscrozi, athomps at sandia.gov.
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Here are various folks who have made significant contributions to
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features in LAMMPS. The most recent contributions are at the top of
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the list.
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:link(sjp,http://www.sandia.gov/~sjplimp)
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pppm GPU single and double : Mike Brown (ORNL)
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pair_style lj/cut/expand : Inderaj Bains (NVIDIA)
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temperature accelerated dynamics (TAD) : Aidan Thompson (Sandia)
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pair reax/c and fix qeq/reax : Metin Aktulga (Purdue, now LBNL)
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DREIDING force field, pair_style hbond/dreiding, etc : Tod Pascal (CalTech)
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fix adapt and compute ti for thermodynamic integreation for free energies : Sai Jayaraman (Sandia)
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pair born and pair gauss : Sai Jayaraman (Sandia)
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stochastic rotation dynamics (SRD) via fix srd : Jemery Lechman (Sandia) and Pieter in 't Veld (BASF)
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ipp Perl script tool : Reese Jones (Sandia)
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eam_database and createatoms tools : Xiaowang Zhou (Sandia)
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electron force field (eFF) : Andres Jaramillo-Botero and Julius Su (Caltech)
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embedded ion method (EIM) potential : Xiaowang Zhou (Sandia)
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COMB potential with charge equilibration : Tzu-Ray Shan (U Florida)
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fix ave/correlate : Benoit Leblanc, Dave Rigby, Paul Saxe (Materials Design) and Reese Jones (Sandia)
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pair_style peri/lps : Mike Parks (Sandia)
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fix msst : Lawrence Fried (LLNL), Evan Reed (LLNL, Stanford)
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thermo_style custom tpcpu & spcpu keywords : Axel Kohlmeyer (Temple U)
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fix rigid/nve, fix rigid/nvt : Tony Sheh and Trung Dac Nguyen (U Michigan)
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public SVN & Git repositories for LAMMPS : Axel Kohlmeyer (Temple U) and Bill Goldman (Sandia)
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fix nvt, fix nph, fix npt, Parinello/Rahman dynamics, fix box/relax : Aidan Thompson (Sandia)
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compute heat/flux : German Samolyuk (ORNL) and Mario Pinto (Computational Research Lab, Pune, India)
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pair yukawa/colloid : Randy Schunk (Sandia)
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fix wall/colloid : Jeremy Lechman (Sandia)
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pair_style dsmc for Direct Simulation Monte Carlo (DSMC) modeling : Paul Crozier (Sandia)
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fix imd for real-time viz and interactive MD : Axel Kohlmeyer (Temple Univ)
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concentration-dependent EAM potential : Alexander Stukowski (Technical University of Darmstadt)
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parallel replica dymamics (PRD) : Mike Brown (Sandia)
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min_style hftn : Todd Plantenga (Sandia)
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fix atc : Reese Jones, Jon Zimmerman, Jeremy Templeton (Sandia)
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dump cfg : Liang Wan (Chinese Academy of Sciences)
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fix nvt with Nose/Hoover chains : Andy Ballard (U Maryland)
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pair_style lj/cut/gpu, pair_style gayberne/gpu : Mike Brown (Sandia)
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pair_style lj96/cut, bond_style table, angle_style table : Chuanfu Luo
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fix langevin tally : Carolyn Phillips (U Michigan)
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compute heat/flux for Green-Kubo : Reese Jones (Sandia), Philip Howell (Siemens), Vikas Varsney (AFRL)
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region cone : Pim Schravendijk
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fix reax/bonds : Aidan Thompson (Sandia)
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pair born/coul/long : Ahmed Ismail (Sandia)
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fix ttm : Paul Crozier (Sandia) and Carolyn Phillips (U Michigan)
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fix box/relax : Aidan Thompson and David Olmsted (Sandia)
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ReaxFF potential : Aidan Thompson (Sandia) and Hansohl Cho (MIT)
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compute cna/atom : Wan Liang (Chinese Academy of Sciences)
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Tersoff/ZBL potential : Dave Farrell (Northwestern U)
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peridynamics : Mike Parks (Sandia)
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fix smd for steered MD : Axel Kohlmeyer (U Penn)
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GROMACS pair potentials : Mark Stevens (Sandia)
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lmp2vmd tool : Axel Kohlmeyer (U Penn)
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compute group/group : Naveen Michaud-Agrawal (Johns Hopkins U)
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USER-CG-CMM package for coarse-graining : Axel Kohlmeyer (U Penn)
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cosine/delta angle potential : Axel Kohlmeyer (U Penn)
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VIM editor add-ons for LAMMPS input scripts : Gerolf Ziegenhain
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pair lubricate : Randy Schunk (Sandia)
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compute ackland/atom : Gerolf Zeigenhain
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kspace_style ewald/n, pair_style lj/coul, pair_style buck/coul : \
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Pieter in 't Veld (Sandia)
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AIREBO bond-order potential : Ase Henry (MIT)
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making LAMMPS a true "object" that can be instantiated multiple times, \
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e.g. as a library : Ben FrantzDale (RPI)
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pymol_asphere viz tool : Mike Brown (Sandia)
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NEMD SLLOD integration : Pieter in 't Veld (Sandia)
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tensile and shear deformations : Pieter in 't Veld (Sandia)
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GayBerne potential : Mike Brown (Sandia)
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ellipsoidal particles : Mike Brown (Sandia)
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colloid potentials : Pieter in 't Veld (Sandia)
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fix heat : Paul Crozier and Ed Webb (Sandia)
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neighbor multi and communicate multi : Pieter in 't Veld (Sandia)
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MATLAB post-processing scripts : Arun Subramaniyan (Purdue)
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triclinic (non-orthogonal) simulation domains : Pieter in 't Veld (Sandia)
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thermo_extract tool: Vikas Varshney (Wright Patterson AFB)
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fix ave/time and fix ave/spatial : Pieter in 't Veld (Sandia)
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MEAM potential : Greg Wagner (Sandia)
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optimized pair potentials for lj/cut, charmm/long, eam, morse : \
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James Fischer (High Performance Technologies), \
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David Richie and Vincent Natoli (Stone Ridge Technologies)
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fix wall/lj126 : Mark Stevens (Sandia)
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Stillinger-Weber and Tersoff potentials : Aidan Thompson and Xiaowang Zhou (Sandia)
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region prism : Pieter in 't Veld (Sandia)
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LJ tail corrections for energy/pressure : Paul Crozier (Sandia)
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fix momentum and recenter : Naveen Michaud-Agrawal (Johns Hopkins U)
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multi-letter variable names : Naveen Michaud-Agrawal (Johns Hopkins U)
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OPLS dihedral potential: Mark Stevens (Sandia)
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POEMS coupled rigid body integrator: Rudranarayan Mukherjee (RPI)
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faster pair hybrid potential: James Fischer \
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(High Performance Technologies, Inc), Vincent Natoli and \
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David Richie (Stone Ridge Technology)
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breakable bond quartic potential: Chris Lorenz and Mark Stevens (Sandia)
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DCD and XTC dump styles: Naveen Michaud-Agrawal (Johns Hopkins U)
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grain boundary orientation fix : Koenraad Janssens and David Olmsted (Sandia)
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lj/smooth pair potential : Craig Maloney (UCSB)
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radius-of-gyration spring fix : Naveen Michaud-Agrawal (Johns Hopkins U) and \
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Paul Crozier (Sandia)
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self spring fix : Naveen Michaud-Agrawal (Johns Hopkins U)
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EAM CoAl and AlCu potentials : Kwang-Reoul Lee (KIST, Korea)
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cosine/squared angle potential : Naveen Michaud-Agrawal (Johns Hopkins U)
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helix dihedral potential : Naveen Michaud-Agrawal (Johns Hopkins U) and \
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Mark Stevens (Sandia)
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Finnis/Sinclair EAM: Tim Lau (MIT)
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dissipative particle dynamics (DPD) potentials: Kurt Smith (U Pitt) and \
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Frank van Swol (Sandia)
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TIP4P potential (4-site water): Ahmed Ismail and Amalie Frischknecht (Sandia)
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uniaxial strain fix: Carsten Svaneborg (Max Planck Institute)
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thermodynamics enhanced by fix quantities: Aidan Thompson (Sandia)
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compressed dump files: Erik Luijten (U Illinois)
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cylindrical indenter fix: Ravi Agrawal (Northwestern U)
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electric field fix: Christina Payne (Vanderbilt U)
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AMBER <-> LAMMPS tool: Keir Novik (Univ College London) and \
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Vikas Varshney (U Akron)
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CHARMM <-> LAMMPS tool: Pieter in 't Veld and Paul Crozier (Sandia)
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Morse bond potential: Jeff Greathouse (Sandia)
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radial distribution functions: Paul Crozier & Jeff Greathouse (Sandia)
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force tables for long-range Coulombics: Paul Crozier (Sandia)
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targeted molecular dynamics (TMD): Paul Crozier (Sandia) and \
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Christian Burisch (Bochum University, Germany)
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FFT support for SGI SCSL (Altix): Jim Shepherd (Ga Tech)
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lmp2cfg and lmp2traj tools: Ara Kooser, Jeff Greathouse, \
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Andrey Kalinichev (Sandia)
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parallel tempering: Mark Sears (Sandia)
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embedded atom method (EAM) potential: Stephen Foiles (Sandia)
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multi-harmonic dihedral potential: Mathias Puetz (Sandia)
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granular force fields and BC: Leo Silbert & Gary Grest (Sandia)
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2d Ewald/PPPM: Paul Crozier (Sandia)
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CHARMM force fields: Paul Crozier (Sandia)
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msi2lmp tool: Steve Lustig (Dupont), Mike Peachey & John Carpenter (Cray)
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HTFN energy minimizer: Todd Plantenga (Sandia)
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class 2 force fields: Eric Simon (Cray)
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NVT/NPT integrators: Mark Stevens (Sandia)
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rRESPA: Mark Stevens & Paul Crozier (Sandia)
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Ewald and PPPM solvers: Roy Pollock (LLNL) : :tb(s=:)
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Other CRADA partners involved in the design and testing of LAMMPS were
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John Carpenter (Mayo Clinic, formerly at Cray Research)
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Terry Stouch (Lexicon Pharmaceuticals, formerly at Bristol Myers Squibb)
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Steve Lustig (Dupont)
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Jim Belak (LLNL) :ul
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