git-svn-id: svn://svn.icms.temple.edu/lammps-ro/trunk@14950 f3b2605a-c512-4ea7-a41b-209d697bcdaa

doc/html/_sources/pair_modify.txt

@@ -0,0 +1,292 @@
+.. index:: pair_modify
+
+pair_modify command
+===================
+
+Syntax
+""""""
+
+.. parsed-literal::
+
+   pair_modify keyword values ...
+
+* one or more keyword/value pairs may be listed
+* keyword = *pair* or *shift* or *mix* or *table* or *table/disp* or *tabinner* or *tabinner/disp* or *tail* or *compute*
+.. parsed-literal::
+
+     *pair* values = sub-style N *special* which wt1 wt2 wt3
+       sub-style = sub-style of :doc:`pair hybrid <pair_hybrid>`
+       N = which instance of sub-style (only if sub-style is used multiple times)
+       *special* which wt1 wt2 wt3 = override *special_bonds* settings (optional)
+       which = *lj/coul* or *lj* or *coul*
+       w1,w2,w3 = 1-2, 1-3, and 1-4 weights from 0.0 to 1.0 inclusive
+     *mix* value = *geometric* or *arithmetic* or *sixthpower*
+     *shift* value = *yes* or *no*
+     *table* value = N
+       2^N = # of values in table
+     *table/disp* value = N
+       2^N = # of values in table
+     *tabinner* value = cutoff
+       cutoff = inner cutoff at which to begin table (distance units)
+     *tabinner/disp* value = cutoff
+       cutoff = inner cutoff at which to begin table (distance units)
+     *tail* value = *yes* or *no*
+     *compute* value = *yes* or *no*
+
+
+
+Examples
+""""""""
+
+.. parsed-literal::
+
+   pair_modify shift yes mix geometric
+   pair_modify tail yes
+   pair_modify table 12
+   pair_modify pair lj/cut compute no
+   pair_modify pair lj/cut/coul/long 1 special lj/coul 0.0 0.0 0.0
+
+Description
+"""""""""""
+
+Modify the parameters of the currently defined pair style.  Not all
+parameters are relevant to all pair styles.
+
+If used, the *pair* keyword must appear first in the list of keywords.
+It can only be used with the :doc:`hybrid and hybrid/overlay <pair_hybrid>` pair styles.  It means that all the
+following parameters will only be modified for the specified
+sub-style.  If the sub-style is defined multiple times, then an
+additional numeric argument *N* must also be specified, which is a
+number from 1 to M where M is the number of times the sub-style was
+listed in the :doc:`pair_style hybrid <pair_hybrid>` command.  The extra
+number indicates which instance of the sub-style the remaining
+keywords will be applied to.  Note that if the *pair* keyword is not
+used, and the pair style is *hybrid* or *hybrid/overlay*\ , then all the
+specified keywords will be applied to all sub-styles.
+
+The *special* keyword can only be used in conjunction with the *pair*
+keyword and must directly follow it. It allows to override the
+:doc:`special_bonds <special_bonds>` settings for the specified sub-style.
+More details are given below.
+
+The *mix* keyword affects pair coefficients for interactions between
+atoms of type I and J, when I != J and the coefficients are not
+explicitly set in the input script.  Note that coefficients for I = J
+must be set explicitly, either in the input script via the
+"pair_coeff" command or in the "Pair Coeffs" section of the :doc:`data file <read_data>`.  For some pair styles it is not necessary to
+specify coefficients when I != J, since a "mixing" rule will create
+them from the I,I and J,J settings.  The pair_modify *mix* value
+determines what formulas are used to compute the mixed coefficients.
+In each case, the cutoff distance is mixed the same way as sigma.
+
+Note that not all pair styles support mixing.  Also, some mix options
+are not available for certain pair styles.  See the doc page for
+individual pair styles for those restrictions.  Note also that the
+:doc:`pair_coeff <pair_coeff>` command also can be to directly set
+coefficients for a specific I != J pairing, in which case no mixing is
+performed.
+
+mix *geometric*
+
+.. parsed-literal::
+
+   epsilon_ij = sqrt(epsilon_i * epsilon_j)
+   sigma_ij = sqrt(sigma_i * sigma_j)
+
+mix *arithmetic*
+
+.. parsed-literal::
+
+   epsilon_ij = sqrt(epsilon_i * epsilon_j)
+   sigma_ij = (sigma_i + sigma_j) / 2
+
+mix *sixthpower*
+
+.. parsed-literal::
+
+   epsilon_ij = (2 * sqrt(epsilon_i*epsilon_j) * sigma_i^3 * sigma_j^3) /
+                (sigma_i^6 + sigma_j^6)
+   sigma_ij = ((sigma_i**6 + sigma_j**6) / 2) ^ (1/6)
+
+The *shift* keyword determines whether a Lennard-Jones potential is
+shifted at its cutoff to 0.0.  If so, this adds an energy term to each
+pairwise interaction which will be included in the thermodynamic
+output, but does not affect pair forces or atom trajectories.  See the
+doc page for individual pair styles to see which ones support this
+option.
+
+The *table* and *table/disp* keywords apply to pair styles with a
+long-range Coulombic term or long-range dispersion term respectively;
+see the doc page for individual styles to see which potentials support
+these options.  If N is non-zero, a table of length 2^N is
+pre-computed for forces and energies, which can shrink their
+computational cost by up to a factor of 2.  The table is indexed via a
+bit-mapping technique :ref:`(Wolff) <Wolff>` and a linear interpolation is
+performed between adjacent table values.  In our experiments with
+different table styles (lookup, linear, spline), this method typically
+gave the best performance in terms of speed and accuracy.
+
+The choice of table length is a tradeoff in accuracy versus speed.  A
+larger N yields more accurate force computations, but requires more
+memory which can slow down the computation due to cache misses.  A
+reasonable value of N is between 8 and 16.  The default value of 12
+(table of length 4096) gives approximately the same accuracy as the
+no-table (N = 0) option.  For N = 0, forces and energies are computed
+directly, using a polynomial fit for the needed erfc() function
+evaluation, which is what earlier versions of LAMMPS did.  Values
+greater than 16 typically slow down the simulation and will not
+improve accuracy; values from 1 to 8 give unreliable results.
+
+The *tabinner* and *tabinner/disp* keywords set an inner cutoff above
+which the pairwise computation is done by table lookup (if tables are
+invoked), for the corresponding Coulombic and dispersion tables
+discussed with the *table* and *table/disp* keywords.  The smaller the
+cutoff is set, the less accurate the table becomes (for a given number
+of table values), which can require use of larger tables.  The default
+cutoff value is sqrt(2.0) distance units which means nearly all
+pairwise interactions are computed via table lookup for simulations
+with "real" units, but some close pairs may be computed directly
+(non-table) for simulations with "lj" units.
+
+When the *tail* keyword is set to *yes*\ , certain pair styles will add
+a long-range VanderWaals tail "correction" to the energy and pressure.
+These corrections are bookkeeping terms which do not affect dynamics,
+unless a constant-pressure simulation is being performed.  See the doc
+page for individual styles to see which support this option.  These
+corrections are included in the calculation and printing of
+thermodynamic quantities (see the :doc:`thermo_style <thermo_style>`
+command).  Their effect will also be included in constant NPT or NPH
+simulations where the pressure influences the simulation box
+dimensions (e.g. the :doc:`fix npt <fix_nh>` and :doc:`fix nph <fix_nh>`
+commands).  The formulas used for the long-range corrections come from
+equation 5 of :ref:`(Sun) <Sun>`.
+
+.. note::
+
+   The tail correction terms are computed at the beginning of each
+   run, using the current atom counts of each atom type.  If atoms are
+   deleted (or lost) or created during a simulation, e.g. via the :doc:`fix gcmc <fix_gcmc>` command, the correction factors are not
+   re-computed.  If you expect the counts to change dramatically, you can
+   break a run into a series of shorter runs so that the correction
+   factors are re-computed more frequently.
+
+Several additional assumptions are inherent in using tail corrections,
+including the following:
+
+* The simulated system is a 3d bulk homogeneous liquid. This option
+  should not be used for systems that are non-liquid, 2d, have a slab
+  geometry (only 2d periodic), or inhomogeneous.
+* G(r), the radial distribution function (rdf), is unity beyond the
+  cutoff, so a fairly large cutoff should be used (i.e. 2.5 sigma for an
+  LJ fluid), and it is probably a good idea to verify this assumption by
+  checking the rdf.  The rdf is not exactly unity beyond the cutoff for
+  each pair of interaction types, so the tail correction is necessarily
+  an approximation.
+The tail corrections are computed at the beginning of each simulation
+run.  If the number of atoms changes during the run, e.g. due to atoms
+leaving the simulation domain, or use of the :doc:`fix gcmc <fix_gcmc>`
+command, then the corrections are not updates to relect the changed
+atom count.  If this is a large effect in your simulation, you should
+break the long run into several short runs, so that the correction
+factors are re-computed multiple times.
+
+* Thermophysical properties obtained from calculations with this option
+  enabled will not be thermodynamically consistent with the truncated
+  force-field that was used.  In other words, atoms do not feel any LJ
+  pair interactions beyond the cutoff, but the energy and pressure
+  reported by the simulation include an estimated contribution from
+  those interactions.
+The *compute* keyword allows pairwise computations to be turned off,
+even though a :doc:`pair_style <pair_style>` is defined.  This is not
+useful for running a real simulation, but can be useful for debugging
+purposes or for performing a :doc:`rerun <rerun>` simulation, when you
+only wish to compute partial forces that do not include the pairwise
+contribution.
+
+Two examples are as follows.  First, this option allows you to perform
+a simulation with :doc:`pair_style hybrid <pair_hybrid>` with only a
+subset of the hybrid sub-styles enabled.  Second, this option allows
+you to perform a simulation with only long-range interactions but no
+short-range pairwise interactions.  Doing this by simply not defining
+a pair style will not work, because the
+:doc:`kspace_style <kspace_style>` command requires a Kspace-compatible
+pair style be defined.
+
+
+----------
+
+
+Use of *special* keyword
+^^^^^^^^^^^^^^^^^^^^^^^^
+
+The *special* keyword allows to override the 1-2, 1-3, and 1-4
+exclusion settings for individual sub-styles of a
+:doc:`hybrid pair style <pair_hybrid>`. It requires 4 arguments similar
+to the :doc:`special_bonds <special_bonds>` command, *which* and
+wt1,wt2,wt3.  The *which* argument can be *lj* to change the
+Lennard-Jones settings, *coul* to change the Coulombic settings,
+or *lj/coul* to change both to the same set of 3 values.  The wt1,wt2,wt3
+values are numeric weights from 0.0 to 1.0 inclusive, for the 1-2,
+1-3, and 1-4 bond topology neighbors, respectively. The *special*
+keyword can only be used in conjunction with the *pair* keyword
+and has to directly follow it.
+
+.. note::
+
+   The global settings specified by the
+   :doc:`special_bonds <special_bonds>` command affect the construction of
+   neighbor lists.  Weights of 0.0 (for 1-2, 1-3, or 1-4 neighbors)
+   exclude those pairs from the neighbor list entirely.  Weights of 1.0
+   store the neighbor with no weighting applied. Thus only global values
+   different from exactly 0.0 or 1.0 can be overridden and an error is
+   generated if the requested setting is not compatible with the global
+   setting. Substituting 1.0e-10 for 0.0 and 0.9999999999 for 1.0 is
+   usually a sufficient workaround in this case without causing a
+   significant error.
+
+
+----------
+
+
+Restrictions
+""""""""""""
+ none
+
+You cannot use *shift* yes with *tail* yes, since those are
+conflicting options.  You cannot use *tail* yes with 2d simulations.
+
+Related commands
+""""""""""""""""
+
+:doc:`pair_style <pair_style>`, :doc:`pair_coeff <pair_coeff>`,
+:doc:`thermo_style <thermo_style>`
+
+Default
+"""""""
+
+The option defaults are mix = geometric, shift = no, table = 12,
+tabinner = sqrt(2.0), tail = no, and compute = yes.
+
+Note that some pair styles perform mixing, but only a certain style of
+mixing.  See the doc pages for individual pair styles for details.
+
+
+----------
+
+
+.. _Wolff:
+
+
+
+**(Wolff)** Wolff and Rudd, Comp Phys Comm, 120, 200-32 (1999).
+
+.. _Sun:
+
+
+
+**(Sun)** Sun, J Phys Chem B, 102, 7338-7364 (1998).
+
+
+.. _lws: http://lammps.sandia.gov
+.. _ld: Manual.html
+.. _lc: Section_commands.html#comm