forked from lijiext/lammps
2630 lines
115 KiB
Plaintext
2630 lines
115 KiB
Plaintext
"Previous Section"_Section_accelerate.html - "LAMMPS WWW Site"_lws - "LAMMPS Documentation"_ld - "LAMMPS Commands"_lc - "Next Section"_Section_example.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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6. How-to discussions :h3
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This section describes how to perform common tasks using LAMMPS.
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6.1 "Restarting a simulation"_#howto_1
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6.2 "2d simulations"_#howto_2
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6.3 "CHARMM, AMBER, and DREIDING force fields"_#howto_3
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6.4 "Running multiple simulations from one input script"_#howto_4
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6.5 "Multi-replica simulations"_#howto_5
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6.6 "Granular models"_#howto_6
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6.7 "TIP3P water model"_#howto_7
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6.8 "TIP4P water model"_#howto_8
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6.9 "SPC water model"_#howto_9
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6.10 "Coupling LAMMPS to other codes"_#howto_10
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6.11 "Visualizing LAMMPS snapshots"_#howto_11
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6.12 "Triclinic (non-orthogonal) simulation boxes"_#howto_12
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6.13 "NEMD simulations"_#howto_13
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6.14 "Finite-size spherical and aspherical particles"_#howto_14
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6.15 "Output from LAMMPS (thermo, dumps, computes, fixes, variables)"_#howto_15
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6.16 "Thermostatting, barostatting and computing temperature"_#howto_16
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6.17 "Walls"_#howto_17
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6.18 "Elastic constants"_#howto_18
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6.19 "Library interface to LAMMPS"_#howto_19
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6.20 "Calculating thermal conductivity"_#howto_20
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6.21 "Calculating viscosity"_#howto_21
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6.22 "Calculating a diffusion coefficient"_#howto_22
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6.23 "Using chunks to calculate system properties"_#howto_23
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6.24 "Setting parameters for the kspace_style pppm/disp command"_#howto_24
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6.25 "Adiabatic core/shell model"_#howto_25 :all(b)
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The example input scripts included in the LAMMPS distribution and
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highlighted in "Section_example"_Section_example.html also show how to
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setup and run various kinds of simulations.
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:line
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:line
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6.1 Restarting a simulation :link(howto_1),h4
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There are 3 ways to continue a long LAMMPS simulation. Multiple
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"run"_run.html commands can be used in the same input script. Each
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run will continue from where the previous run left off. Or binary
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restart files can be saved to disk using the "restart"_restart.html
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command. At a later time, these binary files can be read via a
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"read_restart"_read_restart.html command in a new script. Or they can
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be converted to text data files using the "-r command-line
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switch"_Section_start.html#start_7 and read by a
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"read_data"_read_data.html command in a new script.
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Here we give examples of 2 scripts that read either a binary restart
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file or a converted data file and then issue a new run command to
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continue where the previous run left off. They illustrate what
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settings must be made in the new script. Details are discussed in the
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documentation for the "read_restart"_read_restart.html and
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"read_data"_read_data.html commands.
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Look at the {in.chain} input script provided in the {bench} directory
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of the LAMMPS distribution to see the original script that these 2
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scripts are based on. If that script had the line
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restart 50 tmp.restart :pre
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added to it, it would produce 2 binary restart files (tmp.restart.50
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and tmp.restart.100) as it ran.
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This script could be used to read the 1st restart file and re-run the
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last 50 timesteps:
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read_restart tmp.restart.50 :pre
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neighbor 0.4 bin
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neigh_modify every 1 delay 1 :pre
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fix 1 all nve
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fix 2 all langevin 1.0 1.0 10.0 904297 :pre
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timestep 0.012 :pre
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run 50 :pre
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Note that the following commands do not need to be repeated because
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their settings are included in the restart file: {units, atom_style,
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special_bonds, pair_style, bond_style}. However these commands do
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need to be used, since their settings are not in the restart file:
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{neighbor, fix, timestep}.
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If you actually use this script to perform a restarted run, you will
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notice that the thermodynamic data match at step 50 (if you also put a
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"thermo 50" command in the original script), but do not match at step
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100. This is because the "fix langevin"_fix_langevin.html command
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uses random numbers in a way that does not allow for perfect restarts.
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As an alternate approach, the restart file could be converted to a data
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file as follows:
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lmp_g++ -r tmp.restart.50 tmp.restart.data :pre
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Then, this script could be used to re-run the last 50 steps:
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units lj
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atom_style bond
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pair_style lj/cut 1.12
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pair_modify shift yes
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bond_style fene
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special_bonds 0.0 1.0 1.0 :pre
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read_data tmp.restart.data :pre
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neighbor 0.4 bin
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neigh_modify every 1 delay 1 :pre
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fix 1 all nve
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fix 2 all langevin 1.0 1.0 10.0 904297 :pre
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timestep 0.012 :pre
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reset_timestep 50
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run 50 :pre
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Note that nearly all the settings specified in the original {in.chain}
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script must be repeated, except the {pair_coeff} and {bond_coeff}
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commands since the new data file lists the force field coefficients.
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Also, the "reset_timestep"_reset_timestep.html command is used to tell
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LAMMPS the current timestep. This value is stored in restart files,
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but not in data files.
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:line
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6.2 2d simulations :link(howto_2),h4
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Use the "dimension"_dimension.html command to specify a 2d simulation.
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Make the simulation box periodic in z via the "boundary"_boundary.html
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command. This is the default.
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If using the "create box"_create_box.html command to define a
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simulation box, set the z dimensions narrow, but finite, so that the
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create_atoms command will tile the 3d simulation box with a single z
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plane of atoms - e.g.
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"create box"_create_box.html 1 -10 10 -10 10 -0.25 0.25 :pre
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If using the "read data"_read_data.html command to read in a file of
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atom coordinates, set the "zlo zhi" values to be finite but narrow,
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similar to the create_box command settings just described. For each
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atom in the file, assign a z coordinate so it falls inside the
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z-boundaries of the box - e.g. 0.0.
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Use the "fix enforce2d"_fix_enforce2d.html command as the last
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defined fix to insure that the z-components of velocities and forces
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are zeroed out every timestep. The reason to make it the last fix is
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so that any forces induced by other fixes will be zeroed out.
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Many of the example input scripts included in the LAMMPS distribution
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are for 2d models.
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IMPORTANT NOTE: Some models in LAMMPS treat particles as finite-size
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spheres, as opposed to point particles. In 2d, the particles will
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still be spheres, not disks, meaning their moment of inertia will be
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the same as in 3d.
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:line
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6.3 CHARMM, AMBER, and DREIDING force fields :link(howto_3),h4
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A force field has 2 parts: the formulas that define it and the
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coefficients used for a particular system. Here we only discuss
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formulas implemented in LAMMPS that correspond to formulas commonly
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used in the CHARMM, AMBER, and DREIDING force fields. Setting
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coefficients is done in the input data file via the
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"read_data"_read_data.html command or in the input script with
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commands like "pair_coeff"_pair_coeff.html or
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"bond_coeff"_bond_coeff.html. See "Section_tools"_Section_tools.html
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for additional tools that can use CHARMM or AMBER to assign force
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field coefficients and convert their output into LAMMPS input.
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See "(MacKerell)"_#MacKerell for a description of the CHARMM force
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field. See "(Cornell)"_#Cornell for a description of the AMBER force
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field.
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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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These style choices compute force field formulas that are consistent
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with common options in CHARMM or AMBER. See each command's
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documentation for the formula it computes.
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"bond_style"_bond_harmonic.html harmonic
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"angle_style"_angle_charmm.html charmm
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"dihedral_style"_dihedral_charmm.html charmm
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"pair_style"_pair_charmm.html lj/charmm/coul/charmm
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"pair_style"_pair_charmm.html lj/charmm/coul/charmm/implicit
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"pair_style"_pair_charmm.html lj/charmm/coul/long :ul
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"special_bonds"_special_bonds.html charmm
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"special_bonds"_special_bonds.html amber :ul
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DREIDING is a generic force field developed by the "Goddard
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group"_http://www.wag.caltech.edu at Caltech and is useful for
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predicting structures and dynamics of organic, biological and
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main-group inorganic molecules. The philosophy in DREIDING is to use
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general force constants and geometry parameters based on simple
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hybridization considerations, rather than individual force constants
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and geometric parameters that depend on the particular combinations of
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atoms involved in the bond, angle, or torsion terms. DREIDING has an
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"explicit hydrogen bond term"_pair_hbond_dreiding.html to describe
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interactions involving a hydrogen atom on very electronegative atoms
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(N, O, F).
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See "(Mayo)"_#Mayo for a description of the DREIDING force field
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These style choices compute force field formulas that are consistent
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with the DREIDING force field. See each command's
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documentation for the formula it computes.
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"bond_style"_bond_harmonic.html harmonic
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"bond_style"_bond_morse.html morse :ul
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"angle_style"_angle_harmonic.html harmonic
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"angle_style"_angle_cosine.html cosine
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"angle_style"_angle_cosine_periodic.html cosine/periodic :ul
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"dihedral_style"_dihedral_charmm.html charmm
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"improper_style"_improper_umbrella.html umbrella :ul
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"pair_style"_pair_buck.html buck
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"pair_style"_pair_buck.html buck/coul/cut
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"pair_style"_pair_buck.html buck/coul/long
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"pair_style"_pair_lj.html lj/cut
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"pair_style"_pair_lj.html lj/cut/coul/cut
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"pair_style"_pair_lj.html lj/cut/coul/long :ul
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"pair_style"_pair_hbond_dreiding.html hbond/dreiding/lj
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"pair_style"_pair_hbond_dreiding.html hbond/dreiding/morse :ul
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"special_bonds"_special_bonds.html dreiding :ul
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:line
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6.4 Running multiple simulations from one input script :link(howto_4),h4
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This can be done in several ways. See the documentation for
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individual commands for more details on how these examples work.
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If "multiple simulations" means continue a previous simulation for
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more timesteps, then you simply use the "run"_run.html command
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multiple times. For example, this script
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units lj
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atom_style atomic
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read_data data.lj
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run 10000
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run 10000
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run 10000
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run 10000
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run 10000 :pre
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would run 5 successive simulations of the same system for a total of
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50,000 timesteps.
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If you wish to run totally different simulations, one after the other,
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the "clear"_clear.html command can be used in between them to
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re-initialize LAMMPS. For example, this script
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units lj
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atom_style atomic
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read_data data.lj
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run 10000
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clear
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units lj
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atom_style atomic
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read_data data.lj.new
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run 10000 :pre
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would run 2 independent simulations, one after the other.
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For large numbers of independent simulations, you can use
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"variables"_variable.html and the "next"_next.html and
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"jump"_jump.html commands to loop over the same input script
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multiple times with different settings. For example, this
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script, named in.polymer
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variable d index run1 run2 run3 run4 run5 run6 run7 run8
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shell cd $d
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read_data data.polymer
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run 10000
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shell cd ..
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clear
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next d
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jump in.polymer :pre
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would run 8 simulations in different directories, using a data.polymer
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file in each directory. The same concept could be used to run the
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same system at 8 different temperatures, using a temperature variable
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and storing the output in different log and dump files, for example
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variable a loop 8
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variable t index 0.8 0.85 0.9 0.95 1.0 1.05 1.1 1.15
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log log.$a
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read data.polymer
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velocity all create $t 352839
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fix 1 all nvt $t $t 100.0
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dump 1 all atom 1000 dump.$a
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run 100000
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clear
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next t
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next a
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jump in.polymer :pre
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All of the above examples work whether you are running on 1 or
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multiple processors, but assumed you are running LAMMPS on a single
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partition of processors. LAMMPS can be run on multiple partitions via
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the "-partition" command-line switch as described in "this
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section"_Section_start.html#start_7 of the manual.
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In the last 2 examples, if LAMMPS were run on 3 partitions, the same
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scripts could be used if the "index" and "loop" variables were
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replaced with {universe}-style variables, as described in the
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"variable"_variable.html command. Also, the "next t" and "next a"
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commands would need to be replaced with a single "next a t" command.
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With these modifications, the 8 simulations of each script would run
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on the 3 partitions one after the other until all were finished.
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Initially, 3 simulations would be started simultaneously, one on each
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partition. When one finished, that partition would then start
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the 4th simulation, and so forth, until all 8 were completed.
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:line
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6.5 Multi-replica simulations :link(howto_5),h4
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Several commands in LAMMPS run mutli-replica simulations, meaning
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that multiple instances (replicas) of your simulation are run
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simultaneously, with small amounts of data exchanged between replicas
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periodically.
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These are the relevant commands:
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"neb"_neb.html for nudged elastic band calculations
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"prd"_prd.html for parallel replica dynamics
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"tad"_tad.html for temperature accelerated dynamics
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"temper"_temper.html for parallel tempering
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"fix pimd"_fix_pimd.html for path-integral molecular dynamics (PIMD) :ul
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NEB is a method for finding transition states and barrier energies.
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PRD and TAD are methods for performing accelerated dynamics to find
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and perform infrequent events. Parallel tempering or replica exchange
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runs different replicas at a series of temperature to facilitate
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rare-event sampling.
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These commands can only be used if LAMMPS was built with the REPLICA
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package. See the "Making LAMMPS"_Section_start.html#start_3 section
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for more info on packages.
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PIMD runs different replicas whose individual particles are coupled
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together by springs to model a system or ring-polymers.
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This commands can only be used if LAMMPS was built with the USER-MISC
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package. See the "Making LAMMPS"_Section_start.html#start_3 section
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for more info on packages.
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In all these cases, you must run with one or more processors per
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replica. The processors assigned to each replica are determined at
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run-time by using the "-partition command-line
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switch"_Section_start.html#start_7 to launch LAMMPS on multiple
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partitions, which in this context are the same as replicas. E.g.
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these commands:
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mpirun -np 16 lmp_linux -partition 8x2 -in in.temper
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mpirun -np 8 lmp_linux -partition 8x1 -in in.neb :pre
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would each run 8 replicas, on either 16 or 8 processors. Note the use
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of the "-in command-line switch"_Section_start.html#start_7 to specify
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the input script which is required when running in multi-replica mode.
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Also note that with MPI installed on a machine (e.g. your desktop),
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you can run on more (virtual) processors than you have physical
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processors. Thus the above commands could be run on a
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single-processor (or few-processor) desktop so that you can run
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a multi-replica simulation on more replicas than you have
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physical processors.
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:line
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6.6 Granular models :link(howto_6),h4
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Granular system are composed of spherical particles with a diameter,
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as opposed to point particles. This means they have an angular
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velocity and torque can be imparted to them to cause them to rotate.
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To run a simulation of a granular model, you will want to use
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the following commands:
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"atom_style sphere"_atom_style.html
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"fix nve/sphere"_fix_nve_sphere.html
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"fix gravity"_fix_gravity.html :ul
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This compute
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"compute erotate/sphere"_compute_erotate_sphere.html :ul
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calculates rotational kinetic energy which can be "output with
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thermodynamic info"_Section_howto.html#howto_15.
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Use one of these 3 pair potentials, which compute forces and torques
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between interacting pairs of particles:
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"pair_style"_pair_style.html gran/history
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"pair_style"_pair_style.html gran/no_history
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"pair_style"_pair_style.html gran/hertzian :ul
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These commands implement fix options specific to granular systems:
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"fix freeze"_fix_freeze.html
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"fix pour"_fix_pour.html
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"fix viscous"_fix_viscous.html
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"fix wall/gran"_fix_wall_gran.html :ul
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The fix style {freeze} zeroes both the force and torque of frozen
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atoms, and should be used for granular system instead of the fix style
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{setforce}.
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For computational efficiency, you can eliminate needless pairwise
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computations between frozen atoms by using this command:
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"neigh_modify"_neigh_modify.html exclude :ul
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:line
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6.7 TIP3P water model :link(howto_7),h4
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The TIP3P water model as implemented in CHARMM
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"(MacKerell)"_#MacKerell specifies a 3-site rigid water molecule with
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charges and Lennard-Jones parameters assigned to each of the 3 atoms.
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In LAMMPS the "fix shake"_fix_shake.html command can be used to hold
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the two O-H bonds and the H-O-H angle rigid. A bond style of
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{harmonic} and an angle style of {harmonic} or {charmm} should also be
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used.
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These are the additional parameters (in real units) to set for O and H
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atoms and the water molecule to run a rigid TIP3P-CHARMM model with a
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cutoff. The K values can be used if a flexible TIP3P model (without
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fix shake) is desired. If the LJ epsilon and sigma for HH and OH are
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set to 0.0, it corresponds to the original 1983 TIP3P model
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"(Jorgensen)"_#Jorgensen.
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O mass = 15.9994
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H mass = 1.008
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O charge = -0.834
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H charge = 0.417
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LJ epsilon of OO = 0.1521
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LJ sigma of OO = 3.1507
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LJ epsilon of HH = 0.0460
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LJ sigma of HH = 0.4000
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LJ epsilon of OH = 0.0836
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LJ sigma of OH = 1.7753
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K of OH bond = 450
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r0 of OH bond = 0.9572
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K of HOH angle = 55
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theta of HOH angle = 104.52 :all(b),p
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|
These are the parameters to use for TIP3P with a long-range Coulombic
|
|
solver (e.g. Ewald or PPPM in LAMMPS), see "(Price)"_#Price for
|
|
details:
|
|
|
|
O mass = 15.9994
|
|
H mass = 1.008
|
|
O charge = -0.830
|
|
H charge = 0.415
|
|
LJ epsilon of OO = 0.102
|
|
LJ sigma of OO = 3.188
|
|
LJ epsilon, sigma of OH, HH = 0.0
|
|
K of OH bond = 450
|
|
r0 of OH bond = 0.9572
|
|
K of HOH angle = 55
|
|
theta of HOH angle = 104.52 :all(b),p
|
|
|
|
Wikipedia also has a nice article on "water
|
|
models"_http://en.wikipedia.org/wiki/Water_model.
|
|
|
|
:line
|
|
|
|
6.8 TIP4P water model :link(howto_8),h4
|
|
|
|
The four-point TIP4P rigid water model extends the traditional
|
|
three-point TIP3P model by adding an additional site, usually
|
|
massless, where the charge associated with the oxygen atom is placed.
|
|
This site M is located at a fixed distance away from the oxygen along
|
|
the bisector of the HOH bond angle. A bond style of {harmonic} and an
|
|
angle style of {harmonic} or {charmm} should also be used.
|
|
|
|
A TIP4P model is run with LAMMPS using either this command
|
|
for a cutoff model:
|
|
|
|
"pair_style lj/cut/tip4p/cut"_pair_lj.html
|
|
|
|
or these two commands for a long-range model:
|
|
|
|
"pair_style lj/cut/tip4p/long"_pair_lj.html
|
|
"kspace_style pppm/tip4p"_kspace_style.html :ul
|
|
|
|
For both models, the bond lengths and bond angles should be held fixed
|
|
using the "fix shake"_fix_shake.html command.
|
|
|
|
These are the additional parameters (in real units) to set for O and H
|
|
atoms and the water molecule to run a rigid TIP4P model with a cutoff
|
|
"(Jorgensen)"_#Jorgensen. Note that the OM distance is specified in
|
|
the "pair_style"_pair_style.html command, not as part of the pair
|
|
coefficients.
|
|
|
|
O mass = 15.9994
|
|
H mass = 1.008
|
|
O charge = -1.040
|
|
H charge = 0.520
|
|
r0 of OH bond = 0.9572
|
|
theta of HOH angle = 104.52
|
|
OM distance = 0.15
|
|
LJ epsilon of O-O = 0.1550
|
|
LJ sigma of O-O = 3.1536
|
|
LJ epsilon, sigma of OH, HH = 0.0
|
|
Coulombic cutoff = 8.5 :all(b),p
|
|
|
|
For the TIP4/Ice model (J Chem Phys, 122, 234511 (2005);
|
|
http://dx.doi.org/10.1063/1.1931662) these values can be used:
|
|
|
|
O mass = 15.9994
|
|
H mass = 1.008
|
|
O charge = -1.1794
|
|
H charge = 0.5897
|
|
r0 of OH bond = 0.9572
|
|
theta of HOH angle = 104.52
|
|
OM distance = 0.1577
|
|
LJ epsilon of O-O = 0.21084
|
|
LJ sigma of O-O = 3.1668
|
|
LJ epsilon, sigma of OH, HH = 0.0
|
|
Coulombic cutoff = 8.5 :all(b),p
|
|
|
|
For the TIP4P/2005 model (J Chem Phys, 123, 234505 (2005);
|
|
http://dx.doi.org/10.1063/1.2121687), these values can be used:
|
|
|
|
O mass = 15.9994
|
|
H mass = 1.008
|
|
O charge = -1.1128
|
|
H charge = 0.5564
|
|
r0 of OH bond = 0.9572
|
|
theta of HOH angle = 104.52
|
|
OM distance = 0.1546
|
|
LJ epsilon of O-O = 0.1852
|
|
LJ sigma of O-O = 3.1589
|
|
LJ epsilon, sigma of OH, HH = 0.0
|
|
Coulombic cutoff = 8.5 :all(b),p
|
|
|
|
These are the parameters to use for TIP4P with a long-range Coulombic
|
|
solver (e.g. Ewald or PPPM in LAMMPS):
|
|
|
|
O mass = 15.9994
|
|
H mass = 1.008
|
|
O charge = -1.0484
|
|
H charge = 0.5242
|
|
r0 of OH bond = 0.9572
|
|
theta of HOH angle = 104.52
|
|
OM distance = 0.1250
|
|
LJ epsilon of O-O = 0.16275
|
|
LJ sigma of O-O = 3.16435
|
|
LJ epsilon, sigma of OH, HH = 0.0 :all(b),p
|
|
|
|
Note that the when using the TIP4P pair style, the neighobr list
|
|
cutoff for Coulomb interactions is effectively extended by a distance
|
|
2 * (OM distance), to account for the offset distance of the
|
|
fictitious charges on O atoms in water molecules. Thus it is
|
|
typically best in an efficiency sense to use a LJ cutoff >= Coulomb
|
|
cutoff + 2*(OM distance), to shrink the size of the neighbor list.
|
|
This leads to slightly larger cost for the long-range calculation, so
|
|
you can test the trade-off for your model. The OM distance and the LJ
|
|
and Coulombic cutoffs are set in the "pair_style
|
|
lj/cut/tip4p/long"_pair_lj.html command.
|
|
|
|
Wikipedia also has a nice article on "water
|
|
models"_http://en.wikipedia.org/wiki/Water_model.
|
|
|
|
:line
|
|
|
|
6.9 SPC water model :link(howto_9),h4
|
|
|
|
The SPC water model specifies a 3-site rigid water molecule with
|
|
charges and Lennard-Jones parameters assigned to each of the 3 atoms.
|
|
In LAMMPS the "fix shake"_fix_shake.html command can be used to hold
|
|
the two O-H bonds and the H-O-H angle rigid. A bond style of
|
|
{harmonic} and an angle style of {harmonic} or {charmm} should also be
|
|
used.
|
|
|
|
These are the additional parameters (in real units) to set for O and H
|
|
atoms and the water molecule to run a rigid SPC model.
|
|
|
|
O mass = 15.9994
|
|
H mass = 1.008
|
|
O charge = -0.820
|
|
H charge = 0.410
|
|
LJ epsilon of OO = 0.1553
|
|
LJ sigma of OO = 3.166
|
|
LJ epsilon, sigma of OH, HH = 0.0
|
|
r0 of OH bond = 1.0
|
|
theta of HOH angle = 109.47 :all(b),p
|
|
|
|
Note that as originally proposed, the SPC model was run with a 9
|
|
Angstrom cutoff for both LJ and Coulommbic terms. It can also be used
|
|
with long-range Coulombics (Ewald or PPPM in LAMMPS), without changing
|
|
any of the parameters above, though it becomes a different model in
|
|
that mode of usage.
|
|
|
|
The SPC/E (extended) water model is the same, except
|
|
the partial charge assignemnts change:
|
|
|
|
O charge = -0.8476
|
|
H charge = 0.4238 :all(b),p
|
|
|
|
See the "(Berendsen)"_#Berendsen reference for more details on both
|
|
the SPC and SPC/E models.
|
|
|
|
Wikipedia also has a nice article on "water
|
|
models"_http://en.wikipedia.org/wiki/Water_model.
|
|
|
|
:line
|
|
|
|
6.10 Coupling LAMMPS to other codes :link(howto_10),h4
|
|
|
|
LAMMPS is designed to allow it to be coupled to other codes. For
|
|
example, a quantum mechanics code might compute forces on a subset of
|
|
atoms and pass those forces to LAMMPS. Or a continuum finite element
|
|
(FE) simulation might use atom positions as boundary conditions on FE
|
|
nodal points, compute a FE solution, and return interpolated forces on
|
|
MD atoms.
|
|
|
|
LAMMPS can be coupled to other codes in at least 3 ways. Each has
|
|
advantages and disadvantages, which you'll have to think about in the
|
|
context of your application.
|
|
|
|
(1) Define a new "fix"_fix.html command that calls the other code. In
|
|
this scenario, LAMMPS is the driver code. During its timestepping,
|
|
the fix is invoked, and can make library calls to the other code,
|
|
which has been linked to LAMMPS as a library. This is the way the
|
|
"POEMS"_poems package that performs constrained rigid-body motion on
|
|
groups of atoms is hooked to LAMMPS. See the
|
|
"fix_poems"_fix_poems.html command for more details. See "this
|
|
section"_Section_modify.html of the documentation for info on how to add
|
|
a new fix to LAMMPS.
|
|
|
|
:link(poems,http://www.rpi.edu/~anderk5/lab)
|
|
|
|
(2) Define a new LAMMPS command that calls the other code. This is
|
|
conceptually similar to method (1), but in this case LAMMPS and the
|
|
other code are on a more equal footing. Note that now the other code
|
|
is not called during the timestepping of a LAMMPS run, but between
|
|
runs. The LAMMPS input script can be used to alternate LAMMPS runs
|
|
with calls to the other code, invoked via the new command. The
|
|
"run"_run.html command facilitates this with its {every} option, which
|
|
makes it easy to run a few steps, invoke the command, run a few steps,
|
|
invoke the command, etc.
|
|
|
|
In this scenario, the other code can be called as a library, as in
|
|
(1), or it could be a stand-alone code, invoked by a system() call
|
|
made by the command (assuming your parallel machine allows one or more
|
|
processors to start up another program). In the latter case the
|
|
stand-alone code could communicate with LAMMPS thru files that the
|
|
command writes and reads.
|
|
|
|
See "Section_modify"_Section_modify.html of the documentation for how
|
|
to add a new command to LAMMPS.
|
|
|
|
(3) Use LAMMPS as a library called by another code. In this case the
|
|
other code is the driver and calls LAMMPS as needed. Or a wrapper
|
|
code could link and call both LAMMPS and another code as libraries.
|
|
Again, the "run"_run.html command has options that allow it to be
|
|
invoked with minimal overhead (no setup or clean-up) if you wish to do
|
|
multiple short runs, driven by another program.
|
|
|
|
Examples of driver codes that call LAMMPS as a library are included in
|
|
the examples/COUPLE directory of the LAMMPS distribution; see
|
|
examples/COUPLE/README for more details:
|
|
|
|
simple: simple driver programs in C++ and C which invoke LAMMPS as a
|
|
library :ulb,l
|
|
|
|
lammps_quest: coupling of LAMMPS and "Quest"_quest, to run classical
|
|
MD with quantum forces calculated by a density functional code :l
|
|
|
|
lammps_spparks: coupling of LAMMPS and "SPPARKS"_spparks, to couple
|
|
a kinetic Monte Carlo model for grain growth using MD to calculate
|
|
strain induced across grain boundaries :l,ule
|
|
|
|
:link(quest,http://dft.sandia.gov/Quest)
|
|
:link(spparks,http://www.sandia.gov/~sjplimp/spparks.html)
|
|
|
|
"This section"_Section_start.html#start_5 of the documentation
|
|
describes how to build LAMMPS as a library. Once this is done, you
|
|
can interface with LAMMPS either via C++, C, Fortran, or Python (or
|
|
any other language that supports a vanilla C-like interface). For
|
|
example, from C++ you could create one (or more) "instances" of
|
|
LAMMPS, pass it an input script to process, or execute individual
|
|
commands, all by invoking the correct class methods in LAMMPS. From C
|
|
or Fortran you can make function calls to do the same things. See
|
|
"Section_python"_Section_python.html of the manual for a description
|
|
of the Python wrapper provided with LAMMPS that operates through the
|
|
LAMMPS library interface.
|
|
|
|
The files src/library.cpp and library.h contain the C-style interface
|
|
to LAMMPS. See "Section_howto 19"_Section_howto.html#howto_19 of the
|
|
manual for a description of the interface and how to extend it for
|
|
your needs.
|
|
|
|
Note that the lammps_open() function that creates an instance of
|
|
LAMMPS takes an MPI communicator as an argument. This means that
|
|
instance of LAMMPS will run on the set of processors in the
|
|
communicator. Thus the calling code can run LAMMPS on all or a subset
|
|
of processors. For example, a wrapper script might decide to
|
|
alternate between LAMMPS and another code, allowing them both to run
|
|
on all the processors. Or it might allocate half the processors to
|
|
LAMMPS and half to the other code and run both codes simultaneously
|
|
before syncing them up periodically. Or it might instantiate multiple
|
|
instances of LAMMPS to perform different calculations.
|
|
|
|
:line
|
|
|
|
6.11 Visualizing LAMMPS snapshots :link(howto_11),h4
|
|
|
|
LAMMPS itself does not do visualization, but snapshots from LAMMPS
|
|
simulations can be visualized (and analyzed) in a variety of ways.
|
|
|
|
LAMMPS snapshots are created by the "dump"_dump.html command which can
|
|
create files in several formats. The native LAMMPS dump format is a
|
|
text file (see "dump atom" or "dump custom") which can be visualized
|
|
by the "xmovie"_Section_tools.html#xmovie program, included with the
|
|
LAMMPS package. This produces simple, fast 2d projections of 3d
|
|
systems, and can be useful for rapid debugging of simulation geometry
|
|
and atom trajectories.
|
|
|
|
Several programs included with LAMMPS as auxiliary tools can convert
|
|
native LAMMPS dump files to other formats. See the
|
|
"Section_tools"_Section_tools.html doc page for details. The first is
|
|
the "ch2lmp tool"_Section_tools.html#charmm, which contains a
|
|
lammps2pdb Perl script which converts LAMMPS dump files into PDB
|
|
files. The second is the "lmp2arc tool"_Section_tools.html#arc which
|
|
converts LAMMPS dump files into Accelrys' Insight MD program files.
|
|
The third is the "lmp2cfg tool"_Section_tools.html#cfg which converts
|
|
LAMMPS dump files into CFG files which can be read into the
|
|
"AtomEye"_atomeye visualizer.
|
|
|
|
A Python-based toolkit distributed by our group can read native LAMMPS
|
|
dump files, including custom dump files with additional columns of
|
|
user-specified atom information, and convert them to various formats
|
|
or pipe them into visualization software directly. See the "Pizza.py
|
|
WWW site"_pizza for details. Specifically, Pizza.py can convert
|
|
LAMMPS dump files into PDB, XYZ, "Ensight"_ensight, and VTK formats.
|
|
Pizza.py can pipe LAMMPS dump files directly into the Raster3d and
|
|
RasMol visualization programs. Pizza.py has tools that do interactive
|
|
3d OpenGL visualization and one that creates SVG images of dump file
|
|
snapshots.
|
|
|
|
LAMMPS can create XYZ files directly (via "dump xyz") which is a
|
|
simple text-based file format used by many visualization programs
|
|
including "VMD"_vmd.
|
|
|
|
LAMMPS can create DCD files directly (via "dump dcd") which can be
|
|
read by "VMD"_vmd in conjunction with a CHARMM PSF file. Using this
|
|
form of output avoids the need to convert LAMMPS snapshots to PDB
|
|
files. See the "dump"_dump.html command for more information on DCD
|
|
files.
|
|
|
|
LAMMPS can create XTC files directly (via "dump xtc") which is GROMACS
|
|
file format which can also be read by "VMD"_vmd for visualization.
|
|
See the "dump"_dump.html command for more information on XTC files.
|
|
|
|
:link(pizza,http://www.sandia.gov/~sjplimp/pizza.html)
|
|
:link(vmd,http://www.ks.uiuc.edu/Research/vmd)
|
|
:link(ensight,http://www.ensight.com)
|
|
:link(atomeye,http://mt.seas.upenn.edu/Archive/Graphics/A)
|
|
|
|
:line
|
|
|
|
6.12 Triclinic (non-orthogonal) simulation boxes :link(howto_12),h4
|
|
|
|
By default, LAMMPS uses an orthogonal simulation box to encompass the
|
|
particles. The "boundary"_boundary.html command sets the boundary
|
|
conditions of the box (periodic, non-periodic, etc). The orthogonal
|
|
box has its "origin" at (xlo,ylo,zlo) and is defined by 3 edge vectors
|
|
starting from the origin given by [a] = (xhi-xlo,0,0); [b] =
|
|
(0,yhi-ylo,0); [c] = (0,0,zhi-zlo). The 6 parameters
|
|
(xlo,xhi,ylo,yhi,zlo,zhi) are defined at the time the simulation box
|
|
is created, e.g. by the "create_box"_create_box.html or
|
|
"read_data"_read_data.html or "read_restart"_read_restart.html
|
|
commands. Additionally, LAMMPS defines box size parameters lx,ly,lz
|
|
where lx = xhi-xlo, and similarly in the y and z dimensions. The 6
|
|
parameters, as well as lx,ly,lz, can be output via the "thermo_style
|
|
custom"_thermo_style.html command.
|
|
|
|
LAMMPS also allows simulations to be performed in triclinic
|
|
(non-orthogonal) simulation boxes shaped as a parallelepiped with
|
|
triclinic symmetry. The parallelepiped has its "origin" at
|
|
(xlo,ylo,zlo) and is defined by 3 edge vectors starting from the
|
|
origin given by [a] = (xhi-xlo,0,0); [b] = (xy,yhi-ylo,0); [c] =
|
|
(xz,yz,zhi-zlo). {xy,xz,yz} can be 0.0 or positive or negative values
|
|
and are called "tilt factors" because they are the amount of
|
|
displacement applied to faces of an originally orthogonal box to
|
|
transform it into the parallelepiped. In LAMMPS the triclinic
|
|
simulation box edge vectors [a], [b], and [c] cannot be arbitrary
|
|
vectors. As indicated, [a] must lie on the positive x axis. [b] must
|
|
lie in the xy plane, with strictly positive y component. [c] may have
|
|
any orientation with strictly positive z component. The requirement
|
|
that [a], [b], and [c] have strictly positive x, y, and z components,
|
|
respectively, ensures that [a], [b], and [c] form a complete
|
|
right-handed basis. These restrictions impose no loss of generality,
|
|
since it is possible to rotate/invert any set of 3 crystal basis
|
|
vectors so that they conform to the restrictions.
|
|
|
|
For example, assume that the 3 vectors [A],[B],[C] are the edge
|
|
vectors of a general parallelepiped, where there is no restriction on
|
|
[A],[B],[C] other than they form a complete right-handed basis i.e.
|
|
[A] x [B] . [C] > 0. The equivalent LAMMPS [a],[b],[c] are a linear
|
|
rotation of [A], [B], and [C] and can be computed as follows:
|
|
|
|
:c,image(Eqs/transform.jpg)
|
|
|
|
where A = |[A]| indicates the scalar length of [A]. The ^ hat symbol
|
|
indicates the corresponding unit vector. {beta} and {gamma} are angles
|
|
between the vectors described below. Note that by construction,
|
|
[a], [b], and [c] have strictly positive x, y, and z components, respectively.
|
|
If it should happen that
|
|
[A], [B], and [C] form a left-handed basis, then the above equations
|
|
are not valid for [c]. In this case, it is necessary
|
|
to first apply an inversion. This can be achieved
|
|
by interchanging two basis vectors or by changing the sign of one of them.
|
|
|
|
For consistency, the same rotation/inversion applied to the basis vectors
|
|
must also be applied to atom positions, velocities,
|
|
and any other vector quantities.
|
|
This can be conveniently achieved by first converting to
|
|
fractional coordinates in the
|
|
old basis and then converting to distance coordinates in the new basis.
|
|
The transformation is given by the following equation:
|
|
|
|
:c,image(Eqs/rotate.jpg)
|
|
|
|
where {V} is the volume of the box, [X] is the original vector quantity and
|
|
[x] is the vector in the LAMMPS basis.
|
|
|
|
There is no requirement that a triclinic box be periodic in any
|
|
dimension, though it typically should be in at least the 2nd dimension
|
|
of the tilt (y in xy) if you want to enforce a shift in periodic
|
|
boundary conditions across that boundary. Some commands that work
|
|
with triclinic boxes, e.g. the "fix deform"_fix_deform.html and "fix
|
|
npt"_fix_nh.html commands, require periodicity or non-shrink-wrap
|
|
boundary conditions in specific dimensions. See the command doc pages
|
|
for details.
|
|
|
|
The 9 parameters (xlo,xhi,ylo,yhi,zlo,zhi,xy,xz,yz) are defined at the
|
|
time the simluation box is created. This happens in one of 3 ways.
|
|
If the "create_box"_create_box.html command is used with a region of
|
|
style {prism}, then a triclinic box is setup. See the
|
|
"region"_region.html command for details. If the
|
|
"read_data"_read_data.html command is used to define the simulation
|
|
box, and the header of the data file contains a line with the "xy xz
|
|
yz" keyword, then a triclinic box is setup. See the
|
|
"read_data"_read_data.html command for details. Finally, if the
|
|
"read_restart"_read_restart.html command reads a restart file which
|
|
was written from a simulation using a triclinic box, then a triclinic
|
|
box will be setup for the restarted simulation.
|
|
|
|
Note that you can define a triclinic box with all 3 tilt factors =
|
|
0.0, so that it is initially orthogonal. This is necessary if the box
|
|
will become non-orthogonal, e.g. due to the "fix npt"_fix_nh.html or
|
|
"fix deform"_fix_deform.html commands. Alternatively, you can use the
|
|
"change_box"_change_box.html command to convert a simulation box from
|
|
orthogonal to triclinic and vice versa.
|
|
|
|
As with orthogonal boxes, LAMMPS defines triclinic box size parameters
|
|
lx,ly,lz where lx = xhi-xlo, and similarly in the y and z dimensions.
|
|
The 9 parameters, as well as lx,ly,lz, can be output via the
|
|
"thermo_style custom"_thermo_style.html command.
|
|
|
|
To avoid extremely tilted boxes (which would be computationally
|
|
inefficient), LAMMPS normally requires that no tilt factor can skew
|
|
the box more than half the distance of the parallel box length, which
|
|
is the 1st dimension in the tilt factor (x for xz). This is required
|
|
both when the simulation box is created, e.g. via the
|
|
"create_box"_create_box.html or "read_data"_read_data.html commands,
|
|
as well as when the box shape changes dynamically during a simulation,
|
|
e.g. via the "fix deform"_fix_deform.html or "fix npt"_fix_nh.html
|
|
commands.
|
|
|
|
For example, if xlo = 2 and xhi = 12, then the x box length is 10 and
|
|
the xy tilt factor must be between -5 and 5. Similarly, both xz and
|
|
yz must be between -(xhi-xlo)/2 and +(yhi-ylo)/2. Note that this is
|
|
not a limitation, since if the maximum tilt factor is 5 (as in this
|
|
example), then configurations with tilt = ..., -15, -5, 5, 15, 25,
|
|
... are geometrically all equivalent. If the box tilt exceeds this
|
|
limit during a dynamics run (e.g. via the "fix deform"_fix_deform.html
|
|
command), then the box is "flipped" to an equivalent shape with a tilt
|
|
factor within the bounds, so the run can continue. See the "fix
|
|
deform"_fix_deform.html doc page for further details.
|
|
|
|
One exception to this rule is if the 1st dimension in the tilt
|
|
factor (x for xy) is non-periodic. In that case, the limits on the
|
|
tilt factor are not enforced, since flipping the box in that dimension
|
|
does not change the atom positions due to non-periodicity. In this
|
|
mode, if you tilt the system to extreme angles, the simulation will
|
|
simply become inefficient, due to the highly skewed simulation box.
|
|
|
|
The limitation on not creating a simulation box with a tilt factor
|
|
skewing the box more than half the distance of the parallel box length
|
|
can be overridden via the "box"_box.html command. Setting the {tilt}
|
|
keyword to {large} allows any tilt factors to be specified.
|
|
|
|
Box flips that may occur using the "fix deform"_fix_deform.html or
|
|
"fix npt"_fix_nh.html commands can be turned off using the {flip no}
|
|
option with either of the commands.
|
|
|
|
Note that if a simulation box has a large tilt factor, LAMMPS will run
|
|
less efficiently, due to the large volume of communication needed to
|
|
acquire ghost atoms around a processor's irregular-shaped sub-domain.
|
|
For extreme values of tilt, LAMMPS may also lose atoms and generate an
|
|
error.
|
|
|
|
Triclinic crystal structures are often defined using three lattice
|
|
constants {a}, {b}, and {c}, and three angles {alpha}, {beta} and
|
|
{gamma}. Note that in this nomenclature, the a, b, and c lattice
|
|
constants are the scalar lengths of the edge vectors [a], [b], and [c]
|
|
defined above. The relationship between these 6 quantities
|
|
(a,b,c,alpha,beta,gamma) and the LAMMPS box sizes (lx,ly,lz) =
|
|
(xhi-xlo,yhi-ylo,zhi-zlo) and tilt factors (xy,xz,yz) is as follows:
|
|
|
|
:c,image(Eqs/box.jpg)
|
|
|
|
The inverse relationship can be written as follows:
|
|
|
|
:c,image(Eqs/box_inverse.jpg)
|
|
|
|
The values of {a}, {b}, {c} , {alpha}, {beta} , and {gamma} can be printed
|
|
out or accessed by computes using the
|
|
"thermo_style custom"_thermo_style.html keywords
|
|
{cella}, {cellb}, {cellc}, {cellalpha}, {cellbeta}, {cellgamma},
|
|
respectively.
|
|
|
|
As discussed on the "dump"_dump.html command doc page, when the BOX
|
|
BOUNDS for a snapshot is written to a dump file for a triclinic box,
|
|
an orthogonal bounding box which encloses the triclinic simulation box
|
|
is output, along with the 3 tilt factors (xy, xz, yz) of the triclinic
|
|
box, formatted as follows:
|
|
|
|
ITEM: BOX BOUNDS xy xz yz
|
|
xlo_bound xhi_bound xy
|
|
ylo_bound yhi_bound xz
|
|
zlo_bound zhi_bound yz :pre
|
|
|
|
This bounding box is convenient for many visualization programs and is
|
|
calculated from the 9 triclinic box parameters
|
|
(xlo,xhi,ylo,yhi,zlo,zhi,xy,xz,yz) as follows:
|
|
|
|
xlo_bound = xlo + MIN(0.0,xy,xz,xy+xz)
|
|
xhi_bound = xhi + MAX(0.0,xy,xz,xy+xz)
|
|
ylo_bound = ylo + MIN(0.0,yz)
|
|
yhi_bound = yhi + MAX(0.0,yz)
|
|
zlo_bound = zlo
|
|
zhi_bound = zhi :pre
|
|
|
|
These formulas can be inverted if you need to convert the bounding box
|
|
back into the triclinic box parameters, e.g. xlo = xlo_bound -
|
|
MIN(0.0,xy,xz,xy+xz).
|
|
|
|
One use of triclinic simulation boxes is to model solid-state crystals
|
|
with triclinic symmetry. The "lattice"_lattice.html command can be
|
|
used with non-orthogonal basis vectors to define a lattice that will
|
|
tile a triclinic simulation box via the
|
|
"create_atoms"_create_atoms.html command.
|
|
|
|
A second use is to run Parinello-Rahman dyanamics via the "fix
|
|
npt"_fix_nh.html command, which will adjust the xy, xz, yz tilt
|
|
factors to compensate for off-diagonal components of the pressure
|
|
tensor. The analalog for an "energy minimization"_minimize.html is
|
|
the "fix box/relax"_fix_box_relax.html command.
|
|
|
|
A third use is to shear a bulk solid to study the response of the
|
|
material. The "fix deform"_fix_deform.html command can be used for
|
|
this purpose. It allows dynamic control of the xy, xz, yz tilt
|
|
factors as a simulation runs. This is discussed in the next section
|
|
on non-equilibrium MD (NEMD) simulations.
|
|
|
|
:line
|
|
|
|
6.13 NEMD simulations :link(howto_13),h4
|
|
|
|
Non-equilibrium molecular dynamics or NEMD simulations are typically
|
|
used to measure a fluid's rheological properties such as viscosity.
|
|
In LAMMPS, such simulations can be performed by first setting up a
|
|
non-orthogonal simulation box (see the preceding Howto section).
|
|
|
|
A shear strain can be applied to the simulation box at a desired
|
|
strain rate by using the "fix deform"_fix_deform.html command. The
|
|
"fix nvt/sllod"_fix_nvt_sllod.html command can be used to thermostat
|
|
the sheared fluid and integrate the SLLOD equations of motion for the
|
|
system. Fix nvt/sllod uses "compute
|
|
temp/deform"_compute_temp_deform.html to compute a thermal temperature
|
|
by subtracting out the streaming velocity of the shearing atoms. The
|
|
velocity profile or other properties of the fluid can be monitored via
|
|
the "fix ave/spatial"_fix_ave_spatial.html command.
|
|
|
|
As discussed in the previous section on non-orthogonal simulation
|
|
boxes, the amount of tilt or skew that can be applied is limited by
|
|
LAMMPS for computational efficiency to be 1/2 of the parallel box
|
|
length. However, "fix deform"_fix_deform.html can continuously strain
|
|
a box by an arbitrary amount. As discussed in the "fix
|
|
deform"_fix_deform.html command, when the tilt value reaches a limit,
|
|
the box is flipped to the opposite limit which is an equivalent tiling
|
|
of periodic space. The strain rate can then continue to change as
|
|
before. In a long NEMD simulation these box re-shaping events may
|
|
occur many times.
|
|
|
|
In a NEMD simulation, the "remap" option of "fix
|
|
deform"_fix_deform.html should be set to "remap v", since that is what
|
|
"fix nvt/sllod"_fix_nvt_sllod.html assumes to generate a velocity
|
|
profile consistent with the applied shear strain rate.
|
|
|
|
An alternative method for calculating viscosities is provided via the
|
|
"fix viscosity"_fix_viscosity.html command.
|
|
|
|
:line
|
|
|
|
6.14 Finite-size spherical and aspherical particles :link(howto_14),h4
|
|
|
|
Typical MD models treat atoms or particles as point masses. Sometimes
|
|
it is desirable to have a model with finite-size particles such as
|
|
spheroids or ellipsoids or generalized aspherical bodies. The
|
|
difference is that such particles have a moment of inertia, rotational
|
|
energy, and angular momentum. Rotation is induced by torque coming
|
|
from interactions with other particles.
|
|
|
|
LAMMPS has several options for running simulations with these kinds of
|
|
particles. The following aspects are discussed in turn:
|
|
|
|
atom styles
|
|
pair potentials
|
|
time integration
|
|
computes, thermodynamics, and dump output
|
|
rigid bodies composed of finite-size particles :ul
|
|
|
|
Example input scripts for these kinds of models are in the body,
|
|
colloid, dipole, ellipse, line, peri, pour, and tri directories of the
|
|
"examples directory"_Section_example.html in the LAMMPS distribution.
|
|
|
|
Atom styles :h5
|
|
|
|
There are several "atom styles"_atom_style.html that allow for
|
|
definition of finite-size particles: sphere, dipole, ellipsoid, line,
|
|
tri, peri, and body.
|
|
|
|
The sphere style defines particles that are spheriods and each
|
|
particle can have a unique diameter and mass (or density). These
|
|
particles store an angular velocity (omega) and can be acted upon by
|
|
torque. The "set" command can be used to modify the diameter and mass
|
|
of individual particles, after then are created.
|
|
|
|
The dipole style does not actually define finite-size particles, but
|
|
is often used in conjunction with spherical particles, via a command
|
|
like
|
|
|
|
atom_style hybrid sphere dipole :pre
|
|
|
|
This is because when dipoles interact with each other, they induce
|
|
torques, and a particle must be finite-size (i.e. have a moment of
|
|
inertia) in order to respond and rotate. See the "atom_style
|
|
dipole"_atom_style.html command for details. The "set" command can be
|
|
used to modify the orientation and length of the dipole moment of
|
|
individual particles, after then are created.
|
|
|
|
The ellipsoid style defines particles that are ellipsoids and thus can
|
|
be aspherical. Each particle has a shape, specified by 3 diameters,
|
|
and mass (or density). These particles store an angular momentum and
|
|
their orientation (quaternion), and can be acted upon by torque. They
|
|
do not store an angular velocity (omega), which can be in a different
|
|
direction than angular momentum, rather they compute it as needed.
|
|
The "set" command can be used to modify the diameter, orientation, and
|
|
mass of individual particles, after then are created. It also has a
|
|
brief explanation of what quaternions are.
|
|
|
|
The line style defines line segment particles with two end points and
|
|
a mass (or density). They can be used in 2d simulations, and they can
|
|
be joined together to form rigid bodies which represent arbitrary
|
|
polygons.
|
|
|
|
The tri style defines triangular particles with three corner points
|
|
and a mass (or density). They can be used in 3d simulations, and they
|
|
can be joined together to form rigid bodies which represent arbitrary
|
|
particles with a triangulated surface.
|
|
|
|
The peri style is used with "Peridynamic models"_pair_peri.html and
|
|
defines particles as having a volume, that is used internally in the
|
|
"pair_style peri"_pair_peri.html potentials.
|
|
|
|
The body style allows for definition of particles which can represent
|
|
complex entities, such as surface meshes of discrete points,
|
|
collections of sub-particles, deformable objects, etc. The body style
|
|
is discussed in more detail on the "body"_body.html doc page.
|
|
|
|
Note that if one of these atom styles is used (or multiple styles via
|
|
the "atom_style hybrid"_atom_style.html command), not all particles in
|
|
the system are required to be finite-size or aspherical.
|
|
|
|
For example, in the ellipsoid style, if the 3 shape parameters are set
|
|
to the same value, the particle will be a sphere rather than an
|
|
ellipsoid. If the 3 shape parameters are all set to 0.0 or if the
|
|
diameter is set to 0.0, it will be a point particle. In the line or
|
|
tri style, if the lineflag or triflag is specified as 0, then it
|
|
will be a point particle.
|
|
|
|
Some of the pair styles used to compute pairwise interactions between
|
|
finite-size particles also compute the correct interaction with point
|
|
particles as well, e.g. the interaction between a point particle and a
|
|
finite-size particle or between two point particles. If necessary,
|
|
"pair_style hybrid"_pair_hybrid.html can be used to insure the correct
|
|
interactions are computed for the appropriate style of interactions.
|
|
Likewise, using groups to partition particles (ellipsoids versus
|
|
spheres versus point particles) will allow you to use the appropriate
|
|
time integrators and temperature computations for each class of
|
|
particles. See the doc pages for various commands for details.
|
|
|
|
Also note that for "2d simulations"_dimension.html, atom styles sphere
|
|
and ellipsoid still use 3d particles, rather than as circular disks or
|
|
ellipses. This means they have the same moment of inertia as the 3d
|
|
object. When temperature is computed, the correct degrees of freedom
|
|
are used for rotation in a 2d versus 3d system.
|
|
|
|
Pair potentials :h5
|
|
|
|
When a system with finite-size particles is defined, the particles
|
|
will only rotate and experience torque if the force field computes
|
|
such interactions. These are the various "pair
|
|
styles"_pair_style.html that generate torque:
|
|
|
|
"pair_style gran/history"_pair_gran.html
|
|
"pair_style gran/hertzian"_pair_gran.html
|
|
"pair_style gran/no_history"_pair_gran.html
|
|
"pair_style dipole/cut"_pair_dipole.html
|
|
"pair_style gayberne"_pair_gayberne.html
|
|
"pair_style resquared"_pair_resquared.html
|
|
"pair_style brownian"_pair_brownian.html
|
|
"pair_style lubricate"_pair_lubricate.html
|
|
"pair_style line/lj"_pair_line_lj.html
|
|
"pair_style tri/lj"_pair_tri_lj.html
|
|
"pair_style body"_pair_body.html :ul
|
|
|
|
The granular pair styles are used with spherical particles. The
|
|
dipole pair style is used with the dipole atom style, which could be
|
|
applied to spherical or ellipsoidal particles. The GayBerne and
|
|
REsquared potentials require ellipsoidal particles, though they will
|
|
also work if the 3 shape parameters are the same (a sphere). The
|
|
Brownian and lubrication potentials are used with spherical particles.
|
|
The line, tri, and body potentials are used with line segment,
|
|
triangular, and body particles respectively.
|
|
|
|
Time integration :h5
|
|
|
|
There are several fixes that perform time integration on finite-size
|
|
spherical particles, meaning the integrators update the rotational
|
|
orientation and angular velocity or angular momentum of the particles:
|
|
|
|
"fix nve/sphere"_fix_nve_sphere.html
|
|
"fix nvt/sphere"_fix_nvt_sphere.html
|
|
"fix npt/sphere"_fix_npt_sphere.html :ul
|
|
|
|
Likewise, there are 3 fixes that perform time integration on
|
|
ellipsoidal particles:
|
|
|
|
"fix nve/asphere"_fix_nve_asphere.html
|
|
"fix nvt/asphere"_fix_nvt_asphere.html
|
|
"fix npt/asphere"_fix_npt_asphere.html :ul
|
|
|
|
The advantage of these fixes is that those which thermostat the
|
|
particles include the rotational degrees of freedom in the temperature
|
|
calculation and thermostatting. The "fix langevin"_fix_langevin
|
|
command can also be used with its {omgea} or {angmom} options to
|
|
thermostat the rotational degrees of freedom for spherical or
|
|
ellipsoidal particles. Other thermostatting fixes only operate on the
|
|
translational kinetic energy of finite-size particles.
|
|
|
|
These fixes perform constant NVE time integration on line segment,
|
|
triangular, and body particles:
|
|
|
|
"fix nve/line"_fix_nve_line.html
|
|
"fix nve/tri"_fix_nve_tri.html
|
|
"fix nve/body"_fix_nve_body.html :ul
|
|
|
|
Note that for mixtures of point and finite-size particles, these
|
|
integration fixes can only be used with "groups"_group.html which
|
|
contain finite-size particles.
|
|
|
|
Computes, thermodynamics, and dump output :h5
|
|
|
|
There are several computes that calculate the temperature or
|
|
rotational energy of spherical or ellipsoidal particles:
|
|
|
|
"compute temp/sphere"_compute_temp_sphere.html
|
|
"compute temp/asphere"_compute_temp_asphere.html
|
|
"compute erotate/sphere"_compute_erotate_sphere.html
|
|
"compute erotate/asphere"_compute_erotate_asphere.html :ul
|
|
|
|
These include rotational degrees of freedom in their computation. If
|
|
you wish the thermodynamic output of temperature or pressure to use
|
|
one of these computes (e.g. for a system entirely composed of
|
|
finite-size particles), then the compute can be defined and the
|
|
"thermo_modify"_thermo_modify.html command used. Note that by default
|
|
thermodynamic quantities will be calculated with a temperature that
|
|
only includes translational degrees of freedom. See the
|
|
"thermo_style"_thermo_style.html command for details.
|
|
|
|
These commands can be used to output various attributes of finite-size
|
|
particles:
|
|
|
|
"dump custom"_dump.html
|
|
"compute property/atom"_compute_property_atom.html
|
|
"dump local"_dump.html
|
|
"compute body/local"_compute_body_local.html :ul
|
|
|
|
Attributes include the dipole moment, the angular velocity, the
|
|
angular momentum, the quaternion, the torque, the end-point and
|
|
corner-point coordinates (for line and tri particles), and
|
|
sub-particle attributes of body particles.
|
|
|
|
Rigid bodies composed of finite-size particles :h5
|
|
|
|
The "fix rigid"_fix_rigid.html command treats a collection of
|
|
particles as a rigid body, computes its inertia tensor, sums the total
|
|
force and torque on the rigid body each timestep due to forces on its
|
|
constituent particles, and integrates the motion of the rigid body.
|
|
|
|
If any of the constituent particles of a rigid body are finite-size
|
|
particles (spheres or ellipsoids or line segments or triangles), then
|
|
their contribution to the inertia tensor of the body is different than
|
|
if they were point particles. This means the rotational dynamics of
|
|
the rigid body will be different. Thus a model of a dimer is
|
|
different if the dimer consists of two point masses versus two
|
|
spheroids, even if the two particles have the same mass. Finite-size
|
|
particles that experience torque due to their interaction with other
|
|
particles will also impart that torque to a rigid body they are part
|
|
of.
|
|
|
|
See the "fix rigid" command for example of complex rigid-body models
|
|
it is possible to define in LAMMPS.
|
|
|
|
Note that the "fix shake"_fix_shake.html command can also be used to
|
|
treat 2, 3, or 4 particles as a rigid body, but it always assumes the
|
|
particles are point masses.
|
|
|
|
Also note that body particles cannot be modeled with the "fix
|
|
rigid"_fix_rigid.html command. Body particles are treated by LAMMPS
|
|
as single particles, though they can store internal state, such as a
|
|
list of sub-particles. Individual body partices are typically treated
|
|
as rigid bodies, and their motion integrated with a command like "fix
|
|
nve/body"_fix_nve_body.html. Interactions between pairs of body
|
|
particles are computed via a command like "pair_style
|
|
body"_pair_body.html.
|
|
|
|
:line
|
|
|
|
6.15 Output from LAMMPS (thermo, dumps, computes, fixes, variables) :link(howto_15),h4
|
|
|
|
There are four basic kinds of LAMMPS output:
|
|
|
|
"Thermodynamic output"_thermo_style.html, which is a list
|
|
of quantities printed every few timesteps to the screen and logfile. :ulb,l
|
|
|
|
"Dump files"_dump.html, which contain snapshots of atoms and various
|
|
per-atom values and are written at a specified frequency. :l
|
|
|
|
Certain fixes can output user-specified quantities to files: "fix
|
|
ave/time"_fix_ave_time.html for time averaging, "fix
|
|
ave/spatial"_fix_ave_spatial.html for spatial averaging, and "fix
|
|
print"_fix_print.html for single-line output of
|
|
"variables"_variable.html. Fix print can also output to the
|
|
screen. :l
|
|
|
|
"Restart files"_restart.html. :l,ule
|
|
|
|
A simulation prints one set of thermodynamic output and (optionally)
|
|
restart files. It can generate any number of dump files and fix
|
|
output files, depending on what "dump"_dump.html and "fix"_fix.html
|
|
commands you specify.
|
|
|
|
As discussed below, LAMMPS gives you a variety of ways to determine
|
|
what quantities are computed and printed when the thermodynamics,
|
|
dump, or fix commands listed above perform output. Throughout this
|
|
discussion, note that users can also "add their own computes and fixes
|
|
to LAMMPS"_Section_modify.html which can then generate values that can
|
|
then be output with these commands.
|
|
|
|
The following sub-sections discuss different LAMMPS command related
|
|
to output and the kind of data they operate on and produce:
|
|
|
|
"Global/per-atom/local data"_#global
|
|
"Scalar/vector/array data"_#scalar
|
|
"Thermodynamic output"_#thermo
|
|
"Dump file output"_#dump
|
|
"Fixes that write output files"_#fixoutput
|
|
"Computes that process output quantities"_#computeoutput
|
|
"Fixes that process output quantities"_#fixoutput
|
|
"Computes that generate values to output"_#compute
|
|
"Fixes that generate values to output"_#fix
|
|
"Variables that generate values to output"_#variable
|
|
"Summary table of output options and data flow between commands"_#table :ul
|
|
|
|
Global/per-atom/local data :h5,link(global)
|
|
|
|
Various output-related commands work with three different styles of
|
|
data: global, per-atom, or local. A global datum is one or more
|
|
system-wide values, e.g. the temperature of the system. A per-atom
|
|
datum is one or more values per atom, e.g. the kinetic energy of each
|
|
atom. Local datums are calculated by each processor based on the
|
|
atoms it owns, but there may be zero or more per atom, e.g. a list of
|
|
bond distances.
|
|
|
|
Scalar/vector/array data :h5,link(scalar)
|
|
|
|
Global, per-atom, and local datums can each come in three kinds: a
|
|
single scalar value, a vector of values, or a 2d array of values. The
|
|
doc page for a "compute" or "fix" or "variable" that generates data
|
|
will specify both the style and kind of data it produces, e.g. a
|
|
per-atom vector.
|
|
|
|
When a quantity is accessed, as in many of the output commands
|
|
discussed below, it can be referenced via the following bracket
|
|
notation, where ID in this case is the ID of a compute. The leading
|
|
"c_" would be replaced by "f_" for a fix, or "v_" for a variable:
|
|
|
|
c_ID | entire scalar, vector, or array
|
|
c_ID\[I\] | one element of vector, one column of array
|
|
c_ID\[I\]\[J\] | one element of array :tb(s=|)
|
|
|
|
In other words, using one bracket reduces the dimension of the data
|
|
once (vector -> scalar, array -> vector). Using two brackets reduces
|
|
the dimension twice (array -> scalar). Thus a command that uses
|
|
scalar values as input can typically also process elements of a vector
|
|
or array.
|
|
|
|
Thermodynamic output :h5,link(thermo)
|
|
|
|
The frequency and format of thermodynamic output is set by the
|
|
"thermo"_thermo.html, "thermo_style"_thermo_style.html, and
|
|
"thermo_modify"_thermo_modify.html commands. The
|
|
"thermo_style"_thermo_style.html command also specifies what values
|
|
are calculated and written out. Pre-defined keywords can be specified
|
|
(e.g. press, etotal, etc). Three additional kinds of keywords can
|
|
also be specified (c_ID, f_ID, v_name), where a "compute"_compute.html
|
|
or "fix"_fix.html or "variable"_variable.html provides the value to be
|
|
output. In each case, the compute, fix, or variable must generate
|
|
global values for input to the "thermo_style custom"_dump.html
|
|
command.
|
|
|
|
Note that thermodynamic output values can be "extensive" or
|
|
"intensive". The former scale with the number of atoms in the system
|
|
(e.g. total energy), the latter do not (e.g. temperature). The
|
|
setting for "thermo_modify norm"_thermo_modify.html determines whether
|
|
extensive quantities are normalized or not. Computes and fixes
|
|
produce either extensive or intensive values; see their individual doc
|
|
pages for details. "Equal-style variables"_variable.html produce only
|
|
intensive values; you can include a division by "natoms" in the
|
|
formula if desired, to make an extensive calculation produce an
|
|
intensive result.
|
|
|
|
Dump file output :h5,link(dump)
|
|
|
|
Dump file output is specified by the "dump"_dump.html and
|
|
"dump_modify"_dump_modify.html commands. There are several
|
|
pre-defined formats (dump atom, dump xtc, etc).
|
|
|
|
There is also a "dump custom"_dump.html format where the user
|
|
specifies what values are output with each atom. Pre-defined atom
|
|
attributes can be specified (id, x, fx, etc). Three additional kinds
|
|
of keywords can also be specified (c_ID, f_ID, v_name), where a
|
|
"compute"_compute.html or "fix"_fix.html or "variable"_variable.html
|
|
provides the values to be output. In each case, the compute, fix, or
|
|
variable must generate per-atom values for input to the "dump
|
|
custom"_dump.html command.
|
|
|
|
There is also a "dump local"_dump.html format where the user specifies
|
|
what local values to output. A pre-defined index keyword can be
|
|
specified to enumuerate the local values. Two additional kinds of
|
|
keywords can also be specified (c_ID, f_ID), where a
|
|
"compute"_compute.html or "fix"_fix.html or "variable"_variable.html
|
|
provides the values to be output. In each case, the compute or fix
|
|
must generate local values for input to the "dump local"_dump.html
|
|
command.
|
|
|
|
Fixes that write output files :h5,link(fixoutput)
|
|
|
|
Several fixes take various quantities as input and can write output
|
|
files: "fix ave/time"_fix_ave_time.html, "fix
|
|
ave/spatial"_fix_ave_spatial.html, "fix ave/histo"_fix_ave_histo.html,
|
|
"fix ave/correlate"_fix_ave_correlate.html, and "fix
|
|
print"_fix_print.html.
|
|
|
|
The "fix ave/time"_fix_ave_time.html command enables direct output to
|
|
a file and/or time-averaging of global scalars or vectors. The user
|
|
specifies one or more quantities as input. These can be global
|
|
"compute"_compute.html values, global "fix"_fix.html values, or
|
|
"variables"_variable.html of any style except the atom style which
|
|
produces per-atom values. Since a variable can refer to keywords used
|
|
by the "thermo_style custom"_thermo_style.html command (like temp or
|
|
press) and individual per-atom values, a wide variety of quantities
|
|
can be time averaged and/or output in this way. If the inputs are one
|
|
or more scalar values, then the fix generate a global scalar or vector
|
|
of output. If the inputs are one or more vector values, then the fix
|
|
generates a global vector or array of output. The time-averaged
|
|
output of this fix can also be used as input to other output commands.
|
|
|
|
The "fix ave/spatial"_fix_ave_spatial.html command enables direct
|
|
output to a file of spatial-averaged per-atom quantities like those
|
|
output in dump files, within 1d layers of the simulation box. The
|
|
per-atom quantities can be atom density (mass or number) or atom
|
|
attributes such as position, velocity, force. They can also be
|
|
per-atom quantities calculated by a "compute"_compute.html, by a
|
|
"fix"_fix.html, or by an atom-style "variable"_variable.html. The
|
|
spatial-averaged output of this fix can also be used as input to other
|
|
output commands.
|
|
|
|
The "fix ave/histo"_fix_ave_histo.html command enables direct output
|
|
to a file of histogrammed quantities, which can be global or per-atom
|
|
or local quantities. The histogram output of this fix can also be
|
|
used as input to other output commands.
|
|
|
|
The "fix ave/correlate"_fix_ave_correlate.html command enables direct
|
|
output to a file of time-correlated quantities, which can be global
|
|
scalars. The correlation matrix output of this fix can also be used
|
|
as input to other output commands.
|
|
|
|
The "fix print"_fix_print.html command can generate a line of output
|
|
written to the screen and log file or to a separate file, periodically
|
|
during a running simulation. The line can contain one or more
|
|
"variable"_variable.html values for any style variable except the atom
|
|
style). As explained above, variables themselves can contain
|
|
references to global values generated by "thermodynamic
|
|
keywords"_thermo_style.html, "computes"_compute.html,
|
|
"fixes"_fix.html, or other "variables"_variable.html, or to per-atom
|
|
values for a specific atom. Thus the "fix print"_fix_print.html
|
|
command is a means to output a wide variety of quantities separate
|
|
from normal thermodynamic or dump file output.
|
|
|
|
Computes that process output quantities :h5,link(computeoutput)
|
|
|
|
The "compute reduce"_compute_reduce.html and "compute
|
|
reduce/region"_compute_reduce.html commands take one or more per-atom
|
|
or local vector quantities as inputs and "reduce" them (sum, min, max,
|
|
ave) to scalar quantities. These are produced as output values which
|
|
can be used as input to other output commands.
|
|
|
|
The "compute slice"_compute_slice.html command take one or more global
|
|
vector or array quantities as inputs and extracts a subset of their
|
|
values to create a new vector or array. These are produced as output
|
|
values which can be used as input to other output commands.
|
|
|
|
The "compute property/atom"_compute_property_atom.html command takes a
|
|
list of one or more pre-defined atom attributes (id, x, fx, etc) and
|
|
stores the values in a per-atom vector or array. These are produced
|
|
as output values which can be used as input to other output commands.
|
|
The list of atom attributes is the same as for the "dump
|
|
custom"_dump.html command.
|
|
|
|
The "compute property/local"_compute_property_local.html command takes
|
|
a list of one or more pre-defined local attributes (bond info, angle
|
|
info, etc) and stores the values in a local vector or array. These
|
|
are produced as output values which can be used as input to other
|
|
output commands.
|
|
|
|
The "compute atom/molecule"_compute_atom_molecule.html command takes a
|
|
list of one or more per-atom quantities (from a compute, fix, per-atom
|
|
variable) and sums the quantities on a per-molecule basis. It
|
|
produces a global vector or array as output values which can be used
|
|
as input to other output commands.
|
|
|
|
Fixes that process output quantities :h5,link(fixoutput)
|
|
|
|
The "fix vector"_fix_vector.html command can create global vectors as
|
|
output from global scalars as input, accumulating them one element at
|
|
a time.
|
|
|
|
The "fix ave/atom"_fix_ave_atom.html command performs time-averaging
|
|
of per-atom vectors. The per-atom quantities can be atom attributes
|
|
such as position, velocity, force. They can also be per-atom
|
|
quantities calculated by a "compute"_compute.html, by a
|
|
"fix"_fix.html, or by an atom-style "variable"_variable.html. The
|
|
time-averaged per-atom output of this fix can be used as input to
|
|
other output commands.
|
|
|
|
The "fix store/state"_fix_store_state.html command can archive one or
|
|
more per-atom attributes at a particular time, so that the old values
|
|
can be used in a future calculation or output. The list of atom
|
|
attributes is the same as for the "dump custom"_dump.html command,
|
|
including per-atom quantities calculated by a "compute"_compute.html,
|
|
by a "fix"_fix.html, or by an atom-style "variable"_variable.html.
|
|
The output of this fix can be used as input to other output commands.
|
|
|
|
Computes that generate values to output :h5,link(compute)
|
|
|
|
Every "compute"_compute.html in LAMMPS produces either global or
|
|
per-atom or local values. The values can be scalars or vectors or
|
|
arrays of data. These values can be output using the other commands
|
|
described in this section. The doc page for each compute command
|
|
describes what it produces. Computes that produce per-atom or local
|
|
values have the word "atom" or "local" in their style name. Computes
|
|
without the word "atom" or "local" produce global values.
|
|
|
|
Fixes that generate values to output :h5,link(fix)
|
|
|
|
Some "fixes"_fix.html in LAMMPS produces either global or per-atom or
|
|
local values which can be accessed by other commands. The values can
|
|
be scalars or vectors or arrays of data. These values can be output
|
|
using the other commands described in this section. The doc page for
|
|
each fix command tells whether it produces any output quantities and
|
|
describes them.
|
|
|
|
Variables that generate values to output :h5,link(variable)
|
|
|
|
Every "variables"_variable.html defined in an input script generates
|
|
either a global scalar value or a per-atom vector (only atom-style
|
|
variables) when it is accessed. The formulas used to define equal-
|
|
and atom-style variables can contain references to the thermodynamic
|
|
keywords and to global and per-atom data generated by computes, fixes,
|
|
and other variables. The values generated by variables can be output
|
|
using the other commands described in this section.
|
|
|
|
Summary table of output options and data flow between commands :h5,link(table)
|
|
|
|
This table summarizes the various commands that can be used for
|
|
generating output from LAMMPS. Each command produces output data of
|
|
some kind and/or writes data to a file. Most of the commands can take
|
|
data from other commands as input. Thus you can link many of these
|
|
commands together in pipeline form, where data produced by one command
|
|
is used as input to another command and eventually written to the
|
|
screen or to a file. Note that to hook two commands together the
|
|
output and input data types must match, e.g. global/per-atom/local
|
|
data and scalar/vector/array data.
|
|
|
|
Also note that, as described above, when a command takes a scalar as
|
|
input, that could be an element of a vector or array. Likewise a
|
|
vector input could be a column of an array.
|
|
|
|
Command: Input: Output:
|
|
"thermo_style custom"_thermo_style.html: global scalars: screen, log file:
|
|
"dump custom"_dump.html: per-atom vectors: dump file:
|
|
"dump local"_dump.html: local vectors: dump file:
|
|
"fix print"_fix_print.html: global scalar from variable: screen, file:
|
|
"print"_print.html: global scalar from variable: screen:
|
|
"computes"_compute.html: N/A: global/per-atom/local scalar/vector/array:
|
|
"fixes"_fix.html: N/A: global/per-atom/local scalar/vector/array:
|
|
"variables"_variable.html: global scalars, per-atom vectors: global scalar, per-atom vector:
|
|
"compute reduce"_compute_reduce.html: per-atom/local vectors: global scalar/vector:
|
|
"compute slice"_compute_slice.html: global vectors/arrays: global vector/array:
|
|
"compute property/atom"_compute_property_atom.html: per-atom vectors: per-atom vector/array:
|
|
"compute property/local"_compute_property_local.html: local vectors: local vector/array:
|
|
"compute atom/molecule"_compute_atom_molecule.html: per-atom vectors: global vector/array:
|
|
"fix vector"_fix_vector.html: global scalars: global vector:
|
|
"fix ave/atom"_fix_ave_atom.html: per-atom vectors: per-atom vector/array:
|
|
"fix ave/time"_fix_ave_time.html: global scalars/vectors: global scalar/vector/array, file:
|
|
"fix ave/spatial"_fix_ave_spatial.html: per-atom vectors: global array, file:
|
|
"fix ave/histo"_fix_ave_histo.html: global/per-atom/local scalars and vectors: global array, file:
|
|
"fix ave/correlate"_fix_ave_correlate.html: global scalars: global array, file:
|
|
"fix store/state"_fix_store_state.html: per-atom vectors: per-atom vector/array:
|
|
:tb(s=:)
|
|
|
|
:line
|
|
|
|
6.16 Thermostatting, barostatting, and computing temperature :link(howto_16),h4
|
|
|
|
Thermostatting means controlling the temperature of particles in an MD
|
|
simulation. Barostatting means controlling the pressure. Since the
|
|
pressure includes a kinetic component due to particle velocities, both
|
|
these operations require calculation of the temperature. Typically a
|
|
target temperature (T) and/or pressure (P) is specified by the user,
|
|
and the thermostat or barostat attempts to equilibrate the system to
|
|
the requested T and/or P.
|
|
|
|
Temperature is computed as kinetic energy divided by some number of
|
|
degrees of freedom (and the Boltzmann constant). Since kinetic energy
|
|
is a function of particle velocity, there is often a need to
|
|
distinguish between a particle's advection velocity (due to some
|
|
aggregate motiion of particles) and its thermal velocity. The sum of
|
|
the two is the particle's total velocity, but the latter is often what
|
|
is wanted to compute a temperature.
|
|
|
|
LAMMPS has several options for computing temperatures, any of which
|
|
can be used in thermostatting and barostatting. These "compute
|
|
commands"_compute.html calculate temperature, and the "compute
|
|
pressure"_compute_pressure.html command calculates pressure.
|
|
|
|
"compute temp"_compute_temp.html
|
|
"compute temp/sphere"_compute_temp_sphere.html
|
|
"compute temp/asphere"_compute_temp_asphere.html
|
|
"compute temp/com"_compute_temp_com.html
|
|
"compute temp/deform"_compute_temp_deform.html
|
|
"compute temp/partial"_compute_temp_partial.html
|
|
"compute temp/profile"_compute_temp_profile.html
|
|
"compute temp/ramp"_compute_temp_ramp.html
|
|
"compute temp/region"_compute_temp_region.html :ul
|
|
|
|
All but the first 3 calculate velocity biases directly (e.g. advection
|
|
velocities) that are removed when computing the thermal temperature.
|
|
"Compute temp/sphere"_compute_temp_sphere.html and "compute
|
|
temp/asphere"_compute_temp_asphere.html compute kinetic energy for
|
|
finite-size particles that includes rotational degrees of freedom.
|
|
They both allow for velocity biases indirectly, via an optional extra
|
|
argument, another temperature compute that subtracts a velocity bias.
|
|
This allows the translational velocity of spherical or aspherical
|
|
particles to be adjusted in prescribed ways.
|
|
|
|
Thermostatting in LAMMPS is performed by "fixes"_fix.html, or in one
|
|
case by a pair style. Several thermostatting fixes are available:
|
|
Nose-Hoover (nvt), Berendsen, CSVR, Langevin, and direct rescaling
|
|
(temp/rescale). Dissipative particle dynamics (DPD) thermostatting
|
|
can be invoked via the {dpd/tstat} pair style:
|
|
|
|
"fix nvt"_fix_nh.html
|
|
"fix nvt/sphere"_fix_nvt_sphere.html
|
|
"fix nvt/asphere"_fix_nvt_asphere.html
|
|
"fix nvt/sllod"_fix_nvt_sllod.html
|
|
"fix temp/berendsen"_fix_temp_berendsen.html
|
|
"fix temp/csvr"_fix_temp_csvr.html
|
|
"fix langevin"_fix_langevin.html
|
|
"fix temp/rescale"_fix_temp_rescale.html
|
|
"pair_style dpd/tstat"_pair_dpd.html :ul
|
|
|
|
"Fix nvt"_fix_nh.html only thermostats the translational velocity of
|
|
particles. "Fix nvt/sllod"_fix_nvt_sllod.html also does this, except
|
|
that it subtracts out a velocity bias due to a deforming box and
|
|
integrates the SLLOD equations of motion. See the "NEMD
|
|
simulations"_#howto_13 section of this page for further details. "Fix
|
|
nvt/sphere"_fix_nvt_sphere.html and "fix
|
|
nvt/asphere"_fix_nvt_asphere.html thermostat not only translation
|
|
velocities but also rotational velocities for spherical and aspherical
|
|
particles.
|
|
|
|
DPD thermostatting alters pairwise interactions in a manner analagous
|
|
to the per-particle thermostatting of "fix
|
|
langevin"_fix_langevin.html.
|
|
|
|
Any of the thermostatting fixes can use temperature computes that
|
|
remove bias which has two effects. First, the current calculated
|
|
temperature, which is compared to the requested target temperature, is
|
|
caluclated with the velocity bias removed. Second, the thermostat
|
|
adjusts only the thermal temperature component of the particle's
|
|
velocities, which are the velocities with the bias removed. The
|
|
removed bias is then added back to the adjusted velocities. See the
|
|
doc pages for the individual fixes and for the
|
|
"fix_modify"_fix_modify.html command for instructions on how to assign
|
|
a temperature compute to a thermostatting fix. For example, you can
|
|
apply a thermostat to only the x and z components of velocity by using
|
|
it in conjunction with "compute
|
|
temp/partial"_compute_temp_partial.html. Of you could thermostat only
|
|
the thermal temperature of a streaming flow of particles without
|
|
affecting the streaming velocity, by using "compute
|
|
temp/profile"_compute_temp_profile.html.
|
|
|
|
IMPORTANT NOTE: Only the nvt fixes perform time integration, meaning
|
|
they update the velocities and positions of particles due to forces
|
|
and velocities respectively. The other thermostat fixes only adjust
|
|
velocities; they do NOT perform time integration updates. Thus they
|
|
should be used in conjunction with a constant NVE integration fix such
|
|
as these:
|
|
|
|
"fix nve"_fix_nve.html
|
|
"fix nve/sphere"_fix_nve_sphere.html
|
|
"fix nve/asphere"_fix_nve_asphere.html :ul
|
|
|
|
Barostatting in LAMMPS is also performed by "fixes"_fix.html. Two
|
|
barosttating methods are currently available: Nose-Hoover (npt and
|
|
nph) and Berendsen:
|
|
|
|
"fix npt"_fix_nh.html
|
|
"fix npt/sphere"_fix_npt_sphere.html
|
|
"fix npt/asphere"_fix_npt_asphere.html
|
|
"fix nph"_fix_nh.html
|
|
"fix press/berendsen"_fix_press_berendsen.html :ul
|
|
|
|
The "fix npt"_fix_nh.html commands include a Nose-Hoover thermostat
|
|
and barostat. "Fix nph"_fix_nh.html is just a Nose/Hoover barostat;
|
|
it does no thermostatting. Both "fix nph"_fix_nh.html and "fix
|
|
press/bernendsen"_fix_press_berendsen.html can be used in conjunction
|
|
with any of the thermostatting fixes.
|
|
|
|
As with the thermostats, "fix npt"_fix_nh.html and "fix
|
|
nph"_fix_nh.html only use translational motion of the particles in
|
|
computing T and P and performing thermo/barostatting. "Fix
|
|
npt/sphere"_fix_npt_sphere.html and "fix
|
|
npt/asphere"_fix_npt_asphere.html thermo/barostat using not only
|
|
translation velocities but also rotational velocities for spherical
|
|
and aspherical particles.
|
|
|
|
All of the barostatting fixes use the "compute
|
|
pressure"_compute_pressure.html compute to calculate a current
|
|
pressure. By default, this compute is created with a simple "compute
|
|
temp"_compute_temp.html (see the last argument of the "compute
|
|
pressure"_compute_pressure.html command), which is used to calculated
|
|
the kinetic componenet of the pressure. The barostatting fixes can
|
|
also use temperature computes that remove bias for the purpose of
|
|
computing the kinetic componenet which contributes to the current
|
|
pressure. See the doc pages for the individual fixes and for the
|
|
"fix_modify"_fix_modify.html command for instructions on how to assign
|
|
a temperature or pressure compute to a barostatting fix.
|
|
|
|
IMPORTANT NOTE: As with the thermostats, the Nose/Hoover methods ("fix
|
|
npt"_fix_nh.html and "fix nph"_fix_nh.html) perform time
|
|
integration. "Fix press/berendsen"_fix_press_berendsen.html does NOT,
|
|
so it should be used with one of the constant NVE fixes or with one of
|
|
the NVT fixes.
|
|
|
|
Finally, thermodynamic output, which can be setup via the
|
|
"thermo_style"_thermo_style.html command, often includes temperature
|
|
and pressure values. As explained on the doc page for the
|
|
"thermo_style"_thermo_style.html command, the default T and P are
|
|
setup by the thermo command itself. They are NOT the ones associated
|
|
with any thermostatting or barostatting fix you have defined or with
|
|
any compute that calculates a temperature or pressure. Thus if you
|
|
want to view these values of T and P, you need to specify them
|
|
explicitly via a "thermo_style custom"_thermo_style.html command. Or
|
|
you can use the "thermo_modify"_thermo_modify.html command to
|
|
re-define what temperature or pressure compute is used for default
|
|
thermodynamic output.
|
|
|
|
:line
|
|
|
|
6.17 Walls :link(howto_17),h4
|
|
|
|
Walls in an MD simulation are typically used to bound particle motion,
|
|
i.e. to serve as a boundary condition.
|
|
|
|
Walls in LAMMPS can be of rough (made of particles) or idealized
|
|
surfaces. Ideal walls can be smooth, generating forces only in the
|
|
normal direction, or frictional, generating forces also in the
|
|
tangential direction.
|
|
|
|
Rough walls, built of particles, can be created in various ways. The
|
|
particles themselves can be generated like any other particle, via the
|
|
"lattice"_lattice.html and "create_atoms"_create_atoms.html commands,
|
|
or read in via the "read_data"_read_data.html command.
|
|
|
|
Their motion can be constrained by many different commands, so that
|
|
they do not move at all, move together as a group at constant velocity
|
|
or in response to a net force acting on them, move in a prescribed
|
|
fashion (e.g. rotate around a point), etc. Note that if a time
|
|
integration fix like "fix nve"_fix_nve.html or "fix nvt"_fix_nh.html
|
|
is not used with the group that contains wall particles, their
|
|
positions and velocities will not be updated.
|
|
|
|
"fix aveforce"_fix_aveforce.html - set force on particles to average value, so they move together
|
|
"fix setforce"_fix_setforce.html - set force on particles to a value, e.g. 0.0
|
|
"fix freeze"_fix_freeze.html - freeze particles for use as granular walls
|
|
"fix nve/noforce"_fix_nve_noforce.html - advect particles by their velocity, but without force
|
|
"fix move"_fix_move.html - prescribe motion of particles by a linear velocity, oscillation, rotation, variable :ul
|
|
|
|
The "fix move"_fix_move.html command offers the most generality, since
|
|
the motion of individual particles can be specified with
|
|
"variable"_variable.html formula which depends on time and/or the
|
|
particle position.
|
|
|
|
For rough walls, it may be useful to turn off pairwise interactions
|
|
between wall particles via the "neigh_modify
|
|
exclude"_neigh_modify.html command.
|
|
|
|
Rough walls can also be created by specifying frozen particles that do
|
|
not move and do not interact with mobile particles, and then tethering
|
|
other particles to the fixed particles, via a "bond"_bond_style.html.
|
|
The bonded particles do interact with other mobile particles.
|
|
|
|
Idealized walls can be specified via several fix commands. "Fix
|
|
wall/gran"_fix_wall_gran.html creates frictional walls for use with
|
|
granular particles; all the other commands create smooth walls.
|
|
|
|
"fix wall/reflect"_fix_wall_reflect.html - reflective flat walls
|
|
"fix wall/lj93"_fix_wall.html - flat walls, with Lennard-Jones 9/3 potential
|
|
"fix wall/lj126"_fix_wall.html - flat walls, with Lennard-Jones 12/6 potential
|
|
"fix wall/colloid"_fix_wall.html - flat walls, with "pair_style colloid"_pair_colloid.html potential
|
|
"fix wall/harmonic"_fix_wall.html - flat walls, with repulsive harmonic spring potential
|
|
"fix wall/region"_fix_wall_region.html - use region surface as wall
|
|
"fix wall/gran"_fix_wall_gran.html - flat or curved walls with "pair_style granular"_pair_gran.html potential :ul
|
|
|
|
The {lj93}, {lj126}, {colloid}, and {harmonic} styles all allow the
|
|
flat walls to move with a constant velocity, or oscillate in time.
|
|
The "fix wall/region"_fix_wall_region.html command offers the most
|
|
generality, since the region surface is treated as a wall, and the
|
|
geometry of the region can be a simple primitive volume (e.g. a
|
|
sphere, or cube, or plane), or a complex volume made from the union
|
|
and intersection of primitive volumes. "Regions"_region.html can also
|
|
specify a volume "interior" or "exterior" to the specified primitive
|
|
shape or {union} or {intersection}. "Regions"_region.html can also be
|
|
"dynamic" meaning they move with constant velocity, oscillate, or
|
|
rotate.
|
|
|
|
The only frictional idealized walls currently in LAMMPS are flat or
|
|
curved surfaces specified by the "fix wall/gran"_fix_wall_gran.html
|
|
command. At some point we plan to allow regoin surfaces to be used as
|
|
frictional walls, as well as triangulated surfaces.
|
|
|
|
:line
|
|
|
|
6.18 Elastic constants :link(howto_18),h4
|
|
|
|
Elastic constants characterize the stiffness of a material. The formal
|
|
definition is provided by the linear relation that holds between the
|
|
stress and strain tensors in the limit of infinitesimal deformation.
|
|
In tensor notation, this is expressed as s_ij = C_ijkl * e_kl, where
|
|
the repeated indices imply summation. s_ij are the elements of the
|
|
symmetric stress tensor. e_kl are the elements of the symmetric strain
|
|
tensor. C_ijkl are the elements of the fourth rank tensor of elastic
|
|
constants. In three dimensions, this tensor has 3^4=81 elements. Using
|
|
Voigt notation, the tensor can be written as a 6x6 matrix, where C_ij
|
|
is now the derivative of s_i w.r.t. e_j. Because s_i is itself a
|
|
derivative w.r.t. e_i, it follows that C_ij is also symmetric, with at
|
|
most 7*6/2 = 21 distinct elements.
|
|
|
|
At zero temperature, it is easy to estimate these derivatives by
|
|
deforming the simulation box in one of the six directions using the
|
|
"change_box"_change_box.html command and measuring the change in the
|
|
stress tensor. A general-purpose script that does this is given in the
|
|
examples/elastic directory described in "this
|
|
section"_Section_example.html.
|
|
|
|
Calculating elastic constants at finite temperature is more
|
|
challenging, because it is necessary to run a simulation that perfoms
|
|
time averages of differential properties. One way to do this is to
|
|
measure the change in average stress tensor in an NVT simulations when
|
|
the cell volume undergoes a finite deformation. In order to balance
|
|
the systematic and statistical errors in this method, the magnitude of
|
|
the deformation must be chosen judiciously, and care must be taken to
|
|
fully equilibrate the deformed cell before sampling the stress
|
|
tensor. Another approach is to sample the triclinic cell fluctuations
|
|
that occur in an NPT simulation. This method can also be slow to
|
|
converge and requires careful post-processing "(Shinoda)"_#Shinoda
|
|
|
|
:line
|
|
|
|
6.19 Library interface to LAMMPS :link(howto_19),h4
|
|
|
|
As described in "Section_start 5"_Section_start.html#start_5, LAMMPS
|
|
can be built as a library, so that it can be called by another code,
|
|
used in a "coupled manner"_Section_howto.html#howto_10 with other
|
|
codes, or driven through a "Python interface"_Section_python.html.
|
|
|
|
All of these methodologies use a C-style interface to LAMMPS that is
|
|
provided in the files src/library.cpp and src/library.h. The
|
|
functions therein have a C-style argument list, but contain C++ code
|
|
you could write yourself in a C++ application that was invoking LAMMPS
|
|
directly. The C++ code in the functions illustrates how to invoke
|
|
internal LAMMPS operations. Note that LAMMPS classes are defined
|
|
within a LAMMPS namespace (LAMMPS_NS) if you use them from another C++
|
|
application.
|
|
|
|
Library.cpp contains these 4 functions:
|
|
|
|
void lammps_open(int, char **, MPI_Comm, void **)
|
|
void lammps_close(void *)
|
|
void lammps_file(void *, char *)
|
|
char *lammps_command(void *, char *) :pre
|
|
|
|
The lammps_open() function is used to initialize LAMMPS, passing in a
|
|
list of strings as if they were "command-line
|
|
arguments"_Section_start.html#start_7 when LAMMPS is run in
|
|
stand-alone mode from the command line, and a MPI communicator for
|
|
LAMMPS to run under. It returns a ptr to the LAMMPS object that is
|
|
created, and which is used in subsequent library calls. The
|
|
lammps_open() function can be called multiple times, to create
|
|
multiple instances of LAMMPS.
|
|
|
|
LAMMPS will run on the set of processors in the communicator. This
|
|
means the calling code can run LAMMPS on all or a subset of
|
|
processors. For example, a wrapper script might decide to alternate
|
|
between LAMMPS and another code, allowing them both to run on all the
|
|
processors. Or it might allocate half the processors to LAMMPS and
|
|
half to the other code and run both codes simultaneously before
|
|
syncing them up periodically. Or it might instantiate multiple
|
|
instances of LAMMPS to perform different calculations.
|
|
|
|
The lammps_close() function is used to shut down an instance of LAMMPS
|
|
and free all its memory.
|
|
|
|
The lammps_file() and lammps_command() functions are used to pass a
|
|
file or string to LAMMPS as if it were an input script or single
|
|
command in an input script. Thus the calling code can read or
|
|
generate a series of LAMMPS commands one line at a time and pass it
|
|
thru the library interface to setup a problem and then run it,
|
|
interleaving the lammps_command() calls with other calls to extract
|
|
information from LAMMPS, perform its own operations, or call another
|
|
code's library.
|
|
|
|
Other useful functions are also included in library.cpp. For example:
|
|
|
|
void *lammps_extract_global(void *, char *)
|
|
void *lammps_extract_atom(void *, char *)
|
|
void *lammps_extract_compute(void *, char *, int, int)
|
|
void *lammps_extract_fix(void *, char *, int, int, int, int)
|
|
void *lammps_extract_variable(void *, char *, char *)
|
|
int lammps_get_natoms(void *)
|
|
void lammps_get_coords(void *, double *)
|
|
void lammps_put_coords(void *, double *) :pre
|
|
|
|
These can extract various global or per-atom quantities from LAMMPS as
|
|
well as values calculated by a compute, fix, or variable. The "get"
|
|
and "put" operations can retrieve and reset atom coordinates.
|
|
See the library.cpp file and its associated header file library.h for
|
|
details.
|
|
|
|
The key idea of the library interface is that you can write any
|
|
functions you wish to define how your code talks to LAMMPS and add
|
|
them to src/library.cpp and src/library.h, as well as to the "Python
|
|
interface"_Section_python.html. The routines you add can access or
|
|
change any LAMMPS data you wish. The examples/COUPLE and python
|
|
directories have example C++ and C and Python codes which show how a
|
|
driver code can link to LAMMPS as a library, run LAMMPS on a subset of
|
|
processors, grab data from LAMMPS, change it, and put it back into
|
|
LAMMPS.
|
|
|
|
:line
|
|
|
|
6.20 Calculating thermal conductivity :link(howto_20),h4
|
|
|
|
The thermal conductivity kappa of a material can be measured in at
|
|
least 4 ways using various options in LAMMPS. See the examples/KAPPA
|
|
directory for scripts that implement the 4 methods discussed here for
|
|
a simple Lennard-Jones fluid model. Also, see "this
|
|
section"_Section_howto.html#howto_21 of the manual for an analogous
|
|
discussion for viscosity.
|
|
|
|
The thermal conducitivity tensor kappa is a measure of the propensity
|
|
of a material to transmit heat energy in a diffusive manner as given
|
|
by Fourier's law
|
|
|
|
J = -kappa grad(T)
|
|
|
|
where J is the heat flux in units of energy per area per time and
|
|
grad(T) is the spatial gradient of temperature. The thermal
|
|
conductivity thus has units of energy per distance per time per degree
|
|
K and is often approximated as an isotropic quantity, i.e. as a
|
|
scalar.
|
|
|
|
The first method is to setup two thermostatted regions at opposite
|
|
ends of a simulation box, or one in the middle and one at the end of a
|
|
periodic box. By holding the two regions at different temperatures
|
|
with a "thermostatting fix"_Section_howto.html#howto_13, the energy
|
|
added to the hot region should equal the energy subtracted from the
|
|
cold region and be proportional to the heat flux moving between the
|
|
regions. See the paper by "Ikeshoji and Hafskjold"_#Ikeshoji for
|
|
details of this idea. Note that thermostatting fixes such as "fix
|
|
nvt"_fix_nh.html, "fix langevin"_fix_langevin.html, and "fix
|
|
temp/rescale"_fix_temp_rescale.html store the cumulative energy they
|
|
add/subtract.
|
|
|
|
Alternatively, as a second method, the "fix heat"_fix_heat.html
|
|
command can used in place of thermostats on each of two regions to
|
|
add/subtract specified amounts of energy to both regions. In both
|
|
cases, the resulting temperatures of the two regions can be monitored
|
|
with the "compute temp/region" command and the temperature profile of
|
|
the intermediate region can be monitored with the "fix
|
|
ave/spatial"_fix_ave_spatial.html and "compute
|
|
ke/atom"_compute_ke_atom.html commands.
|
|
|
|
The third method is to perform a reverse non-equilibrium MD simulation
|
|
using the "fix thermal/conductivity"_fix_thermal_conductivity.html
|
|
command which implements the rNEMD algorithm of Muller-Plathe.
|
|
Kinetic energy is swapped between atoms in two different layers of the
|
|
simulation box. This induces a temperature gradient between the two
|
|
layers which can be monitored with the "fix
|
|
ave/spatial"_fix_ave_spatial.html and "compute
|
|
ke/atom"_compute_ke_atom.html commands. The fix tallies the
|
|
cumulative energy transfer that it performs. See the "fix
|
|
thermal/conductivity"_fix_thermal_conductivity.html command for
|
|
details.
|
|
|
|
The fourth method is based on the Green-Kubo (GK) formula which
|
|
relates the ensemble average of the auto-correlation of the heat flux
|
|
to kappa. The heat flux can be calculated from the fluctuations of
|
|
per-atom potential and kinetic energies and per-atom stress tensor in
|
|
a steady-state equilibrated simulation. This is in contrast to the
|
|
two preceding non-equilibrium methods, where energy flows continuously
|
|
between hot and cold regions of the simulation box.
|
|
|
|
The "compute heat/flux"_compute_heat_flux.html command can calculate
|
|
the needed heat flux and describes how to implement the Green_Kubo
|
|
formalism using additional LAMMPS commands, such as the "fix
|
|
ave/correlate"_fix_ave_correlate.html command to calculate the needed
|
|
auto-correlation. See the doc page for the "compute
|
|
heat/flux"_compute_heat_flux.html command for an example input script
|
|
that calculates the thermal conductivity of solid Ar via the GK
|
|
formalism.
|
|
|
|
:line
|
|
|
|
6.21 Calculating viscosity :link(howto_21),h4
|
|
|
|
The shear viscosity eta of a fluid can be measured in at least 4 ways
|
|
using various options in LAMMPS. See the examples/VISCOSITY directory
|
|
for scripts that implement the 4 methods discussed here for a simple
|
|
Lennard-Jones fluid model. Also, see "this
|
|
section"_Section_howto.html#howto_20 of the manual for an analogous
|
|
discussion for thermal conductivity.
|
|
|
|
Eta is a measure of the propensity of a fluid to transmit momentum in
|
|
a direction perpendicular to the direction of velocity or momentum
|
|
flow. Alternatively it is the resistance the fluid has to being
|
|
sheared. It is given by
|
|
|
|
J = -eta grad(Vstream)
|
|
|
|
where J is the momentum flux in units of momentum per area per time.
|
|
and grad(Vstream) is the spatial gradient of the velocity of the fluid
|
|
moving in another direction, normal to the area through which the
|
|
momentum flows. Viscosity thus has units of pressure-time.
|
|
|
|
The first method is to perform a non-equlibrium MD (NEMD) simulation
|
|
by shearing the simulation box via the "fix deform"_fix_deform.html
|
|
command, and using the "fix nvt/sllod"_fix_nvt_sllod.html command to
|
|
thermostat the fluid via the SLLOD equations of motion.
|
|
Alternatively, as a second method, one or more moving walls can be
|
|
used to shear the fluid in between them, again with some kind of
|
|
thermostat that modifies only the thermal (non-shearing) components of
|
|
velocity to prevent the fluid from heating up.
|
|
|
|
In both cases, the velocity profile setup in the fluid by this
|
|
procedure can be monitored by the "fix
|
|
ave/spatial"_fix_ave_spatial.html command, which determines
|
|
grad(Vstream) in the equation above. E.g. the derivative in the
|
|
y-direction of the Vx component of fluid motion or grad(Vstream) =
|
|
dVx/dy. The Pxy off-diagonal component of the pressure or stress
|
|
tensor, as calculated by the "compute pressure"_compute_pressure.html
|
|
command, can also be monitored, which is the J term in the equation
|
|
above. See "this section"_Section_howto.html#howto_13 of the manual
|
|
for details on NEMD simulations.
|
|
|
|
The third method is to perform a reverse non-equilibrium MD simulation
|
|
using the "fix viscosity"_fix_viscosity.html command which implements
|
|
the rNEMD algorithm of Muller-Plathe. Momentum in one dimension is
|
|
swapped between atoms in two different layers of the simulation box in
|
|
a different dimension. This induces a velocity gradient which can be
|
|
monitored with the "fix ave/spatial"_fix_ave_spatial.html command.
|
|
The fix tallies the cummulative momentum transfer that it performs.
|
|
See the "fix viscosity"_fix_viscosity.html command for details.
|
|
|
|
The fourth method is based on the Green-Kubo (GK) formula which
|
|
relates the ensemble average of the auto-correlation of the
|
|
stress/pressure tensor to eta. This can be done in a steady-state
|
|
equilibrated simulation which is in contrast to the two preceding
|
|
non-equilibrium methods, where momentum flows continuously through the
|
|
simulation box.
|
|
|
|
Here is an example input script that calculates the viscosity of
|
|
liquid Ar via the GK formalism:
|
|
|
|
# Sample LAMMPS input script for viscosity of liquid Ar :pre
|
|
|
|
units real
|
|
variable T equal 86.4956
|
|
variable V equal vol
|
|
variable dt equal 4.0
|
|
variable p equal 400 # correlation length
|
|
variable s equal 5 # sample interval
|
|
variable d equal $p*$s # dump interval :pre
|
|
|
|
# convert from LAMMPS real units to SI :pre
|
|
|
|
variable kB equal 1.3806504e-23 # \[J/K/] Boltzmann
|
|
variable atm2Pa equal 101325.0
|
|
variable A2m equal 1.0e-10
|
|
variable fs2s equal 1.0e-15
|
|
variable convert equal $\{atm2Pa\}*$\{atm2Pa\}*$\{fs2s\}*$\{A2m\}*$\{A2m\}*$\{A2m\} :pre
|
|
|
|
# setup problem :pre
|
|
|
|
dimension 3
|
|
boundary p p p
|
|
lattice fcc 5.376 orient x 1 0 0 orient y 0 1 0 orient z 0 0 1
|
|
region box block 0 4 0 4 0 4
|
|
create_box 1 box
|
|
create_atoms 1 box
|
|
mass 1 39.948
|
|
pair_style lj/cut 13.0
|
|
pair_coeff * * 0.2381 3.405
|
|
timestep $\{dt\}
|
|
thermo $d :pre
|
|
|
|
# equilibration and thermalization :pre
|
|
|
|
velocity all create $T 102486 mom yes rot yes dist gaussian
|
|
fix NVT all nvt temp $T $T 10 drag 0.2
|
|
run 8000 :pre
|
|
|
|
# viscosity calculation, switch to NVE if desired :pre
|
|
|
|
#unfix NVT
|
|
#fix NVE all nve :pre
|
|
|
|
reset_timestep 0
|
|
variable pxy equal pxy
|
|
variable pxz equal pxz
|
|
variable pyz equal pyz
|
|
fix SS all ave/correlate $s $p $d &
|
|
v_pxy v_pxz v_pyz type auto file S0St.dat ave running
|
|
variable scale equal $\{convert\}/($\{kB\}*$T)*$V*$s*$\{dt\}
|
|
variable v11 equal trap(f_SS\[3\])*$\{scale\}
|
|
variable v22 equal trap(f_SS\[4\])*$\{scale\}
|
|
variable v33 equal trap(f_SS\[5\])*$\{scale\}
|
|
thermo_style custom step temp press v_pxy v_pxz v_pyz v_v11 v_v22 v_v33
|
|
run 100000
|
|
variable v equal (v_v11+v_v22+v_v33)/3.0
|
|
variable ndens equal count(all)/vol
|
|
print "average viscosity: $v \[Pa.s/] @ $T K, $\{ndens\} /A^3" :pre
|
|
|
|
:line
|
|
|
|
6.22 Calculating a diffusion coefficient :link(howto_22),h4
|
|
|
|
The diffusion coefficient D of a material can be measured in at least
|
|
2 ways using various options in LAMMPS. See the examples/DIFFUSE
|
|
directory for scripts that implement the 2 methods discussed here for
|
|
a simple Lennard-Jones fluid model.
|
|
|
|
The first method is to measure the mean-squared displacement (MSD) of
|
|
the system, via the "compute msd"_compute_msd.html command. The slope
|
|
of the MSD versus time is proportional to the diffusion coefficient.
|
|
The instantaneous MSD values can be accumulated in a vector via the
|
|
"fix vector"_fix_vector.html command, and a line fit to the vector to
|
|
compute its slope via the "variable slope"_variable.html function, and
|
|
thus extract D.
|
|
|
|
The second method is to measure the velocity auto-correlation function
|
|
(VACF) of the system, via the "compute vacf"_compute_vacf.html
|
|
command. The time-integral of the VACF is proportional to the
|
|
diffusion coefficient. The instantaneous VACF values can be
|
|
accumulated in a vector via the "fix vector"_fix_vector.html command,
|
|
and time integrated via the "variable trap"_variable.html function,
|
|
and thus extract D.
|
|
|
|
:line
|
|
|
|
6.23 Using chunks to calculate system properties :link(howto_23),h4
|
|
|
|
In LAMMS, "chunks" are collections of atoms, as defined by the
|
|
"compute chunk/atom"_compute_chunk_atom.html command, which assigns
|
|
each atom to a chunk ID (or to no chunk at all). The number of chunks
|
|
and the assignment of chunk IDs to atoms can be static or change over
|
|
time. Examples of "chunks" are molecules or spatial bins or atoms
|
|
with similar values (e.g. coordination number or potential energy).
|
|
|
|
The per-atom chunk IDs can be used as input to two other kinds of
|
|
commands, to calculate various properties of a system:
|
|
|
|
"fix ave/chunk"_fix_ave_chunk.html
|
|
any of the "compute */chunk"_compute.html commands :ul
|
|
|
|
Here, each of the 3 kinds of chunk-related commands is briefly
|
|
overviewed. Then some examples are given of how to compute different
|
|
properties with chunk commands.
|
|
|
|
Compute chunk/atom command: :h5
|
|
|
|
This compute can assign atoms to chunks of various styles. Only atoms
|
|
in the specified group and optional specified region are assigned to a
|
|
chunk. Here are some possible chunk definitions:
|
|
|
|
atoms in same molecule | chunk ID = molecule ID |
|
|
atoms of same atom type | chunk ID = atom type |
|
|
all atoms with same atom property (charge, radius, etc) | chunk ID = output of compute property/atom |
|
|
atoms in same cluster | chunk ID = output of "compute cluster/atom"_compute_cluster_atom.html command |
|
|
atoms in same spatial bin | chunk ID = bin ID |
|
|
atoms in same rigid body | chunk ID = molecule ID used to define rigid bodies |
|
|
atoms with similar potential energy | chunk ID = output of "compute pe/atom"_compute_pe_atom.html |
|
|
atoms with same local defect structure | chunk ID = output of "compute centro/atom"_compute_centro_atom.html or "compute coord/atom"_compute_coord_atom.html command :tb(s=|,c=2)
|
|
|
|
Note that chunk IDs are integer values, so for atom properties or
|
|
computes that produce a floating point value, they will be truncated
|
|
to an integer. You could also use the compute in a variable that
|
|
scales the floating point value to spread it across multiple intergers.
|
|
|
|
Spatial bins can be of various kinds, e.g. 1d bins = slabs, 2d bins =
|
|
pencils, 3d bins = boxes, spherical bins, cylindrical bins.
|
|
|
|
This compute also calculates the number of chunks {Nchunk}, which is
|
|
used by other commands to tally per-chunk data. {Nchunk} can be a
|
|
static value or change over time (e.g. the number of clusters). The
|
|
chunk ID for an individual atom can also be static (e.g. a molecule
|
|
ID), or dynamic (e.g. what spatial bin an atom is in as it moves).
|
|
|
|
Note that this compute allows the per-atom output of other
|
|
"computes"_compute.html, "fixes"_fix.html, and
|
|
"variables"_variable.html to be used to define chunk IDs for each
|
|
atom. This means you can write your own compute or fix to output a
|
|
per-atom quantity to use as chunk ID. See
|
|
"Section_modify"_Section_modify.html of the documentation for how to
|
|
do this. You can also define a "per-atom variable"_variable.html in
|
|
the input script that uses a formula to generate a chunk ID for each
|
|
atom.
|
|
|
|
Fix ave/chunk command: :h5
|
|
|
|
This fix takes the ID of a "compute
|
|
chunk/atom"_compute_chunk_atom.html command as input. For each chunk,
|
|
it then sums one or more specified per-atom values over the atoms in
|
|
each chunk. The per-atom values can be any atom property, such as
|
|
velocity, force, charge, potential energy, kinetic energy, stress,
|
|
etc. Additional keywords are defined for per-chunk properties like
|
|
density and temperature. More generally any per-atom value generated
|
|
by other "computes"_compute.html, "fixes"_fix.html, and "per-atom
|
|
variables"_variable.html, can be summed over atoms in each chunk.
|
|
|
|
Similar to other averaging fixes, this fix allows the summed per-chunk
|
|
values to be time-averaged in various ways, and output to a file. The
|
|
fix produces a global array as output with one row of values per
|
|
chunk.
|
|
|
|
Compute */chunk commands: :h5
|
|
|
|
Currently the following computes operate on chunks of atoms to produce
|
|
per-chunk values.
|
|
|
|
"compute com/chunk"_compute_com_chunk.html
|
|
"compute gyration/chunk"_compute_gyration_chunk.html
|
|
"compute inertia/chunk"_compute_inertia_chunk.html
|
|
"compute msd/chunk"_compute_msd_chunk.html
|
|
"compute property/chunk"_compute_property_chunk.html
|
|
"compute temp/chunk"_compute_temp_chunk.html
|
|
"compute torque/chunk"_compute_vcm_chunk.html
|
|
"compute vcm/chunk"_compute_vcm_chunk.html :ul
|
|
|
|
They each take the ID of a "compute
|
|
chunk/atom"_compute_chunk_atom.html command as input. As their names
|
|
indicate, they calculate the center-of-mass, radius of gyration,
|
|
moments of inertia, mean-squared displacement, temperature, torque,
|
|
and velocity of center-of-mass for each chunk of atoms. The "compute
|
|
property/chunk"_compute_property_chunk.html command can tally the
|
|
count of atoms in each chunk and extract other per-chunk properties.
|
|
|
|
The reason these various calculations are not part of the "fix
|
|
ave/chunk command"_fix_ave_chunk.html, is that each requires a more
|
|
complicated operation than simply summing and averaging over per-atom
|
|
values in each chunk. For example, many of them require calculation
|
|
of a center of mass, which requires summing mass*position over the
|
|
atoms and then dividing by summed mass.
|
|
|
|
All of these computes produce a global vector or global array as
|
|
output, wih one or more values per chunk. They can be used
|
|
in various ways:
|
|
|
|
As input to the "fix ave/time"_fix_ave_time.html command, which can
|
|
write the values to a file and optionally time average them. :ulb,l
|
|
|
|
As input to the "fix ave/histo"_fix_ave_histo.html command to
|
|
histogram values across chunks. E.g. a histogram of cluster sizes or
|
|
molecule diffusion rates. :l
|
|
|
|
As input to special functions of "equal-style
|
|
variables"_variable.html, like sum() and max(). E.g. to find the
|
|
largest cluster or fastest diffusing molecule. :l,ule
|
|
|
|
Example calculations with chunks :h5
|
|
|
|
Here are eaxmples using chunk commands to calculate various
|
|
properties:
|
|
|
|
(1) Average velocity in each of 1000 2d spatial bins:
|
|
|
|
compute cc1 all chunk/atom bin/2d x 0.0 0.1 y lower 0.01 units reduced
|
|
fix 1 all ave/chunk 100 10 1000 cc1 vx vy file tmp.out :pre
|
|
|
|
(2) Temperature in each spatial bin, after subtracting a flow
|
|
velocity:
|
|
|
|
compute cc1 all chunk/atom bin/2d x 0.0 0.1 y lower 0.1 units reduced
|
|
compute vbias all temp/profile 1 0 0 y 10
|
|
fix 1 all ave/chunk 100 10 1000 cc1 temp bias vbias file tmp.out :pre
|
|
|
|
(3) Center of mass of each molecule:
|
|
|
|
compute cc1 all chunk/atom molecule
|
|
compute myChunk all com/chunk cc1
|
|
fix 1 all ave/time 100 1 100 c_myChunk file tmp.out mode vector :pre
|
|
|
|
(4) Total force on each molecule and ave/max across all molecules:
|
|
|
|
compute cc1 all chunk/atom molecule
|
|
fix 1 all ave/chunk 1000 1 1000 cc1 fx fy fz file tmp.out
|
|
variable xave equal ave(f_1[2])
|
|
variable xmax equal max(f_1[2])
|
|
thermo 1000
|
|
thermo_style custom step temp v_xave v_xmax :pre
|
|
|
|
(5) Histogram of cluster sizes:
|
|
|
|
compute cluster all cluster/atom 1.0
|
|
compute cc1 all chunk/atom c_cluster compress yes
|
|
compute size all property/chunk cc1 count
|
|
fix 1 all ave/histo 100 1 100 0 20 20 c_size mode vector ave running beyond ignore file tmp.histo :pre
|
|
|
|
:line
|
|
|
|
6.24 Setting parameters for the "kspace_style pppm/disp"_kspace_style.html command :link(howto_24),h4
|
|
|
|
The PPPM method computes interactions by splitting the pair potential
|
|
into two parts, one of which is computed in a normal pairwise fashion,
|
|
the so-called real-space part, and one of which is computed using the
|
|
Fourier transform, the so called reciprocal-space or kspace part. For
|
|
both parts, the potential is not computed exactly but is approximated.
|
|
Thus, there is an error in both parts of the computation, the
|
|
real-space and the kspace error. The just mentioned facts are true
|
|
both for the PPPM for Coulomb as well as dispersion interactions. The
|
|
deciding difference - and also the reason why the parameters for
|
|
pppm/disp have to be selected with more care - is the impact of the
|
|
errors on the results: The kspace error of the PPPM for Coulomb and
|
|
dispersion interaction and the real-space error of the PPPM for
|
|
Coulomb interaction have the character of noise. In contrast, the
|
|
real-space error of the PPPM for dispersion has a clear physical
|
|
interpretation: the underprediction of cohesion. As a consequence, the
|
|
real-space error has a much stronger effect than the kspace error on
|
|
simulation results for pppm/disp. Parameters must thus be chosen in a
|
|
way that this error is much smaller than the kspace error.
|
|
|
|
When using pppm/disp and not making any specifications on the PPPM
|
|
parameters via the kspace modify command, parameters will be tuned
|
|
such that the real-space error and the kspace error are equal. This
|
|
will result in simulations that are either inaccurate or slow, both of
|
|
which is not desirable. For selecting parameters for the pppm/disp
|
|
that provide fast and accurate simulations, there are two approaches,
|
|
which both have their up- and downsides.
|
|
|
|
The first approach is to set desired real-space an kspace accuracies
|
|
via the {kspace_modify force/disp/real} and {kspace_modify
|
|
force/disp/kspace} commands. Note that the accuracies have to be
|
|
specified in force units and are thus dependend on the chosen unit
|
|
settings. For real units, 0.0001 and 0.002 seem to provide reasonable
|
|
accurate and efficient computations for the real-space and kspace
|
|
accuracies. 0.002 and 0.05 work well for most systems using lj
|
|
units. PPPM parameters will be generated based on the desired
|
|
accuracies. The upside of this approach is that it usually provides a
|
|
good set of parameters and will work for both the {kspace_modify diff
|
|
ad} and {kspace_modify diff ik} options. The downside of the method
|
|
is that setting the PPPM parameters will take some time during the
|
|
initialization of the simulation.
|
|
|
|
The second approach is to set the parameters for the pppm/disp
|
|
explicitly using the {kspace_modify mesh/disp}, {kspace_modify
|
|
order/disp}, and {kspace_modify gewald/disp} commands. This approach
|
|
requires a more experienced user who understands well the impact of
|
|
the choice of parameters on the simulation accuracy and
|
|
performance. This approach provides a fast initialization of the
|
|
simulation. However, it is sensitive to errors: A combination of
|
|
parameters that will perform well for one system might result in
|
|
far-from-optimal conditions for other simulations. For example,
|
|
parametes that provide accurate and fast computations for
|
|
all-atomistic force fields can provide insufficient accuracy or
|
|
united-atomistic force fields (which is related to that the latter
|
|
typically have larger dispersion coefficients).
|
|
|
|
To avoid inaccurate or inefficient simulations, the pppm/disp stops
|
|
simulations with an error message if no action is taken to control the
|
|
PPPM parameters. If the automatic parameter generation is desired and
|
|
real-space and kspace accuracies are desired to be equal, this error
|
|
message can be suppressed using the {kspace_modify disp/auto yes}
|
|
command.
|
|
|
|
A reasonable approach that combines the upsides of both methods is to
|
|
make the first run using the {kspace_modify force/disp/real} and
|
|
{kspace_modify force/disp/kspace} commands, write down the PPPM
|
|
parameters from the outut, and specify these parameters using the
|
|
second approach in subsequent runs (which have the same composition,
|
|
force field, and approximately the same volume).
|
|
|
|
Concerning the performance of the pppm/disp there are two more things
|
|
to consider. The first is that when using the pppm/disp, the cutoff
|
|
parameter does no longer affect the accuracy of the simulation
|
|
(subject to that gewald/disp is adjusted when changing the cutoff).
|
|
The performance can thus be increased by examining different values
|
|
for the cutoff parameter. A lower bound for the cutoff is only set by
|
|
the truncation error of the repulsive term of pair potentials.
|
|
|
|
The second is that the mixing rule of the pair style has an impact on
|
|
the computation time when using the pppm/disp. Fastest computations
|
|
are achieved when using the geometric mixing rule. Using the
|
|
arithmetic mixing rule substantially increases the computational cost.
|
|
The computational overhead can be reduced using the {kspace_modify
|
|
mix/disp geom} and {kspace_modify splittol} commands. The first
|
|
command simply enforces geometric mixing of the dispersion
|
|
coeffiecients in kspace computations. This introduces some error in
|
|
the computations but will also significantly speed-up the
|
|
simulations. The second keyword sets the accuracy with which the
|
|
dispersion coefficients are approximated using a matrix factorization
|
|
approach. This may result in better accuracy then using the first
|
|
command, but will usually also not provide an equally good increase of
|
|
efficiency.
|
|
|
|
Finally, pppm/disp can also be used when no mixing rules apply.
|
|
This can be achieved using the {kspace_modify mix/disp none} command.
|
|
Note that the code does not check automatically whether any mixing
|
|
rule is fulfilled. If mixing rules do not apply, the user will have
|
|
to specify this command explicitly.
|
|
|
|
:line
|
|
|
|
6.25 Adiabatic core/shell model :link(howto_25),h4
|
|
|
|
The adiabatic core-shell model by "Mitchell and
|
|
Finchham"_#MitchellFinchham is a simple method for adding
|
|
polarizability to a system. In order to mimic the electron shell of
|
|
an ion, a ghost atom is attached to it. This way the ions are split
|
|
into a core and a shell where the latter is meant to react to the
|
|
electrostatic environment inducing polarizability.
|
|
|
|
Technically, shells are attached to the cores by a spring force f =
|
|
k*r where k is a parametrized spring constant and r is the distance
|
|
between the core and the shell. The charges of the core and the shell
|
|
add up to the ion charge, thus q(ion) = q(core) + q(shell). In a
|
|
similar fashion the mass of the ion is distributed on the core and the
|
|
shell with the core having the larger mass.
|
|
|
|
To run this model in LAMMPS, "atom_style"_atom_style.html {full} can
|
|
be used since atom charge and bonds are needed. Each kind of
|
|
core/shell pair requires two atom types and a bond type. The core and
|
|
shell of a core/shell pair should be bonded to each other with a
|
|
harmonic bond that provides the spring force. For example, a data file
|
|
for NaCl, as found in examples/coreshell, has this format:
|
|
|
|
432 atoms # core and shell atoms
|
|
216 bonds # number of core/shell springs :pre
|
|
|
|
4 atom types # 2 cores and 2 shells for Na and Cl
|
|
2 bond types :pre
|
|
|
|
0.0 24.09597 xlo xhi
|
|
0.0 24.09597 ylo yhi
|
|
0.0 24.09597 zlo zhi :pre
|
|
|
|
Masses # core/shell mass ratio = 0.1 :pre
|
|
|
|
1 20.690784 # Na core
|
|
2 31.90500 # Cl core
|
|
3 2.298976 # Na shell
|
|
4 3.54500 # Cl shell :pre
|
|
|
|
Atoms :pre
|
|
|
|
1 1 2 1.5005 0.00000000 0.00000000 0.00000000 # core of core/shell pair 1
|
|
2 1 4 -2.5005 0.00000000 0.00000000 0.00000000 # shell of core/shell pair 1
|
|
3 2 1 1.5056 4.01599500 4.01599500 4.01599500 # core of core/shell pair 2
|
|
4 2 3 -0.5056 4.01599500 4.01599500 4.01599500 # shell of core/shell pair 2
|
|
(...) :pre
|
|
|
|
Bonds # Bond topology for spring forces :pre
|
|
|
|
1 2 1 2 # spring for core/shell pair 1
|
|
2 2 3 4 # spring for core/shell pair 2
|
|
(...) :pre
|
|
|
|
Non-Coulombic (e.g. Lennard-Jones) pairwise interactions are only
|
|
defined between the shells. Coulombic interactions are defined
|
|
between all cores and shells. If desired, additional bonds can be
|
|
specified between cores.
|
|
|
|
The "special_bonds"_special_bonds.html command should be used to
|
|
turn-off the Coulombic interaction within core/shell pairs, since that
|
|
interaction is set by the bond spring. This is done using the
|
|
"special_bonds"_special_bonds.html command with a 1-2 weight = 0.0,
|
|
which is the default value.
|
|
|
|
Since the core/shell model permits distances of r = 0.0 between the
|
|
core and shell, a pair style with a "cs" suffix needs to be used to
|
|
implement a valid long-range Coulombic correction. Several such pair
|
|
styles are provided in the CORESHELL package. See "this doc
|
|
page"_pair_cs.html for details. All of the core/shell enabled pair
|
|
styles require the use of a long-range Coulombic solver, as specified
|
|
by the "kspace_style"_kspace_style.html command. Either the PPPM or
|
|
Ewald solvers can be used.
|
|
|
|
For the NaCL example problem, these pair style and bond style settings
|
|
are used:
|
|
|
|
pair_style born/coul/long/cs 20.0 20.0
|
|
pair_coeff * * 0.0 1.000 0.00 0.00 0.00
|
|
pair_coeff 3 3 487.0 0.23768 0.00 1.05 0.50 #Na-Na
|
|
pair_coeff 3 4 145134.0 0.23768 0.00 6.99 8.70 #Na-Cl
|
|
pair_coeff 4 4 405774.0 0.23768 0.00 72.40 145.40 #Cl-Cl :pre
|
|
|
|
bond_style harmonic
|
|
bond_coeff 1 63.014 0.0
|
|
bond_coeff 2 25.724 0.0 :pre
|
|
|
|
When running dynamics with the adiabatic core/shell model, the
|
|
following issues should be considered. Since the relative motion of
|
|
the core and shell particles corresponds to the polarization, typical
|
|
thermostats can alter the polarization behaviour, meaining the shell
|
|
will not react freely to its electrostatic environment. Therefore
|
|
it's typically desirable to decouple the relative motion of the
|
|
core/shell pair, which is an imaginary degree of freedom, from the
|
|
real physical system. To do that, the "compute
|
|
temp/cs"_compute_temp_cs.html command can be used, in conjunction with
|
|
any of the thermostat fixes, such as "fix nvt"_fix_nh.html or "fix
|
|
langevin"_fix_langevin. This compute uses the center-of-mass velocity
|
|
of the core/shell pairs to calculate a temperature, and insures that
|
|
velocity is what is rescaled for thermostatting purposes. The
|
|
"compute temp/cs"_compute_temp_cs.html command requires input of two
|
|
groups, one for the core atoms, another for the shell atoms. These
|
|
can be defined using the "group {type}"_group.html command. Note that
|
|
to perform thermostatting using this definition of temperature, the
|
|
"fix modify temp"_fix_modify.html command should be used to assign the
|
|
comptue to the thermostat fix. Likewise the "thermo_modify
|
|
temp"_thermo_modify.html command can be used to make this temperature
|
|
be output for the overall system.
|
|
|
|
For the NaCl example, this can be done as follows:
|
|
|
|
group cores type 1 2
|
|
group shells type 3 4
|
|
compute CSequ all temp/cs cores shells
|
|
fix thermoberendsen all temp/berendsen 1427 1427 0.4 # thermostat for the true physical system
|
|
fix thermostatequ all nve # integrator as needed for the berendsen thermostat
|
|
fix_modify thermoberendsen temp CSequ
|
|
thermo_modify temp CSequ # output of center-of-mass derived temperature :pre
|
|
|
|
When intializing the velocities of a system with core/shell pairs, it
|
|
is also desirable to not introduce energy into the relative motion of
|
|
the core/shell particles, but only assign a center-of-mass velocity to
|
|
the pairs. This can be done by using the {bias} keyword of the
|
|
"velocity create"_velocity.html command and assigning the "compute
|
|
temp/cs"_compute_temp_cs.html command to the {temp} keyword of the
|
|
"velocity"_velocity.html commmand, e.g.
|
|
|
|
velocity all create 1427 134 bias yes temp CSequ
|
|
velocity all scale 1427 temp CSequ :pre
|
|
|
|
It is important to note that the polarizability of the core/shell
|
|
pairs is based on their relative motion. Therefore the choice of
|
|
spring force and mass ratio need to ensure much faster relative motion
|
|
of the 2 atoms within the core/shell pair than their center-of-mass
|
|
velocity. This allow the shells to effectively react instantaneously
|
|
to the electrostatic environment. This fast movement also limits the
|
|
timestep size that can be used.
|
|
|
|
Additionally, the mass mismatch of the core and shell particles means
|
|
that only a small amount of energy is transfered to the decoupled
|
|
imaginary degrees of freedom. However, this transfer will typically
|
|
lead to a a small drift in total energy over time. This internal
|
|
energy can be monitored using the "compute
|
|
chunk/atom"_compute_chunk_atom.html and "compute
|
|
temp/chunk"_compute_temp_chunk.html commands. The internal kinetic
|
|
energies of each core/shell pair can then be summed using the sum()
|
|
special functino of the "variable"_variable.html command. Or they can
|
|
be time/averaged and output using the "fix ave/time"_fix_ave_time.html
|
|
command. To use these commands, each core/shell pair must be defined
|
|
as a "chunk". If each core/shell pair is defined as its own molecule,
|
|
the molecule ID can be used to define the chunks. If cores are bonded
|
|
to each other to form larger molecules, then another way to define the
|
|
chunks is to use the "fix property/atom"_fix_property_atom.html to
|
|
assign a core/shell ID to each atom via a special field in the data
|
|
file read by the "read_data"_read_data.html command. This field can
|
|
then be accessed by the "compute
|
|
property/atom"_compute_property_atom.html command, to use as input to
|
|
the "compute chunk/atom"_compute_chunk_atom.html command to define the
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core/shell pairs as chunks.
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For example,
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fix csinfo all property/atom i_CSID # property/atom command
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read_data NaCl_CS_x0.1_prop.data fix csinfo NULL CS-Info # atom property added in the data-file
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compute prop all property/atom i_CSID
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compute cs_chunk all chunk/atom c_prop
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compute cstherm all temp/chunk cs_chunk temp internal com yes cdof 3.0 # note the chosen degrees of freedom for the core/shell pairs
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fix ave_chunk all ave/time 10 1 10 c_cstherm file chunk.dump mode vector :pre
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The additional section in the date file would be formatted like this:
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CS-Info # header of additional section :pre
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1 1 # column 1 = atom ID, column 2 = core/shell ID
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2 1
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3 2
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4 2
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5 3
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6 3
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7 4
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8 4
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(...) :pre
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:line
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:line
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:link(Berendsen)
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[(Berendsen)] Berendsen, Grigera, Straatsma, J Phys Chem, 91,
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6269-6271 (1987).
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:link(Cornell)
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[(Cornell)] Cornell, Cieplak, Bayly, Gould, Merz, Ferguson,
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Spellmeyer, Fox, Caldwell, Kollman, JACS 117, 5179-5197 (1995).
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:link(Horn)
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[(Horn)] Horn, Swope, Pitera, Madura, Dick, Hura, and Head-Gordon,
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J Chem Phys, 120, 9665 (2004).
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:link(Ikeshoji)
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[(Ikeshoji)] Ikeshoji and Hafskjold, Molecular Physics, 81, 251-261
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(1994).
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:link(MacKerell)
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[(MacKerell)] MacKerell, Bashford, Bellott, Dunbrack, Evanseck, Field,
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Fischer, Gao, Guo, Ha, et al, J Phys Chem, 102, 3586 (1998).
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:link(Mayo)
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[(Mayo)] Mayo, Olfason, Goddard III, J Phys Chem, 94, 8897-8909
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(1990).
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:link(Jorgensen)
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[(Jorgensen)] Jorgensen, Chandrasekhar, Madura, Impey, Klein, J Chem
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Phys, 79, 926 (1983).
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:link(Price)
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[(Price)] Price and Brooks, J Chem Phys, 121, 10096 (2004).
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:link(Shinoda)
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[(Shinoda)] Shinoda, Shiga, and Mikami, Phys Rev B, 69, 134103 (2004).
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:link(MitchellFinchham)
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[(Mitchell and Finchham)] Mitchell, Finchham, J Phys Condensed Matter,
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5, 1031-1038 (1993).
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