# pair_style hybrid command

Accelerator Variants: *hybrid/kk*

# pair_style hybrid/overlay command

Accelerator Variants: *hybrid/overlay/kk*

# pair_style hybrid/scaled command

## Syntax

``` LAMMPS
pair_style hybrid style1 args style2 args ...
pair_style hybrid/overlay style1 args style2 args ...
pair_style hybrid/scaled factor1 style1 args factor2 style 2 args ...
```

-   style1,style2 = list of one or more pair styles and their arguments
-   factor1,factor2 = scale factors for pair styles, may be a variable

## Examples

``` LAMMPS
pair_style hybrid lj/cut/coul/cut 10.0 eam lj/cut 5.0
pair_coeff 1*2 1*2 eam niu3
pair_coeff 3 3 lj/cut/coul/cut 1.0 1.0
pair_coeff 1*2 3 lj/cut 0.5 1.2

pair_style hybrid/overlay lj/cut 2.5 coul/long 2.0
pair_coeff * * lj/cut 1.0 1.0
pair_coeff * * coul/long

pair_style hybrid/scaled 0.5 tersoff 0.5 sw
pair_coeff * * tersoff Si.tersoff Si
pair_coeff * * sw Si.sw Si

variable one equal ramp(1.0,0.0)
variable two equal 1.0-v_one
pair_style hybrid/scaled v_one lj/cut 2.5 v_two morse 2.5
pair_coeff 1 1 lj/cut 1.0 1.0 2.5
pair_coeff 1 1 morse 1.0 1.0 1.0 2.5
```

## Description

The *hybrid*, *hybrid/overlay*, and *hybrid/scaled* styles enable the
use of multiple pair styles in one simulation. With the *hybrid* style,
exactly one pair style is assigned to each pair of atom types. With the
*hybrid/overlay* and *hybrid/scaled* styles, one or more pair styles can
be assigned to each pair of atom types. The assignment of pair styles to
type pairs is made via the [pair_coeff](pair_coeff) command. The major
difference between the *hybrid/overlay* and *hybrid/scaled* styles is
that the *hybrid/scaled* adds a scale factor for each sub-style
contribution to forces, energies and stresses. Because of the added
complexity, the *hybrid/scaled* style has more overhead and thus may be
slower than *hybrid/overlay*.

Here are two examples of hybrid simulations. The *hybrid* style could be
used for a simulation of a metal droplet on a LJ surface. The metal
atoms interact with each other via an *eam* potential, the surface atoms
interact with each other via a *lj/cut* potential, and the metal/surface
interaction is also computed via a *lj/cut* potential. The
*hybrid/overlay* style could be used as in the second example above,
where multiple potentials are superimposed in an additive fashion to
compute the interaction between atoms. In this example, using *lj/cut*
and *coul/long* together gives the same result as if the
*lj/cut/coul/long* potential were used by itself. In this case, it would
be more efficient to use the single combined potential, but in general
any combination of pair potentials can be used together in to produce an
interaction that is not encoded in any single pair_style file, e.g.
adding Coulombic forces between granular particles. Another limitation
of using the *hybrid/overlay* variant, that it does not generate
*lj/cut* parameters for mixed atom types from a mixing rule due to
restrictions discussed below.

If the *hybrid/scaled* style is used instead of *hybrid/overlay*,
contributions from sub-styles are weighted by their scale factors, which
may be fractional or even negative. Furthermore the scale factors may be
variables that may change during a simulation. This enables switching
smoothly between two different pair styles or two different parameter
sets during a run in a similar fashion as could be done with [fix
adapt](fix_adapt) or [fix alchemy](fix_alchemy).

All pair styles that will be used are listed as \"sub-styles\" following
the *hybrid* or *hybrid/overlay* keyword, in any order. In case of the
*hybrid/scaled* pair style, each sub-style is prefixed with a scale
factor. The scale factor is either a floating point number or an equal
style (or equivalent) variable. Each sub-style\'s name is followed by
its usual arguments, as illustrated in the examples above. See the doc
pages of the individual pair styles for a listing and explanation of the
appropriate arguments for them.

Note that an individual pair style can be used multiple times as a
sub-style. For efficiency reasons this should only be done if your model
requires it. E.g. if you have different regions of Si and C atoms and
wish to use a Tersoff potential for pure Si for one set of atoms, and a
Tersoff potential for pure C for the other set (presumably with some
third potential for Si-C interactions), then the sub-style *tersoff*
could be listed twice. But if you just want to use a Lennard-Jones or
other pairwise potential for several different atom type pairs in your
model, then you should just list the sub-style once and use the
pair_coeff command to assign parameters for the different type pairs.

:::: note
::: title
Note
:::

There is one exception to this option to list an individual pair style
multiple times: GPU-enabled pair styles in the GPU package. This is
because the GPU package currently assumes that only one instance of a
pair style is being used.
::::

In the pair_coeff commands, the name of a pair style must be added after
the I,J type specification, with the remaining coefficients being those
appropriate to that style. If the pair style is used multiple times in
the pair_style command, then an additional numeric argument 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 pair style command. The extra number
indicates which instance of the sub-style these coefficients apply to.

For example, consider a simulation with 3 atom types: types 1 and 2 are
Ni atoms, type 3 are LJ atoms with charges. The following commands would
set up a hybrid simulation:

``` LAMMPS
pair_style hybrid eam/alloy lj/cut/coul/cut 10.0 lj/cut 8.0
pair_coeff * * eam/alloy nialhjea Ni Ni NULL
pair_coeff 3 3 lj/cut/coul/cut 1.0 1.0
pair_coeff 1*2 3 lj/cut 0.8 1.3
```

As an example of using the same pair style multiple times, consider a
simulation with 2 atom types. Type 1 is Si, type 2 is C. The following
commands would model the Si atoms with Tersoff, the C atoms with
Tersoff, and the cross-interactions with Lennard-Jones:

``` LAMMPS
pair_style hybrid lj/cut 2.5 tersoff tersoff
pair_coeff * * tersoff 1 Si.tersoff Si NULL
pair_coeff * * tersoff 2 C.tersoff NULL C
pair_coeff 1 2 lj/cut 1.0 1.5
```

It is not recommended to read pair coefficients for a hybrid style from
a \"Pair Coeffs\" or \"PairIJ Coeffs\" section of a data file via the
[read_data](read_data) command, since those sections expect a fixed
number of lines, either one line per atom type or one line pair pair of
atom types, respectively. When reading from a data file, the lines of
the \"Pair Coeffs\" and \"PairIJ Coeffs\" are changed in the same way as
the *pair_coeff* command, i.e. the name of the pair style to which the
parameters apply must follow the atom type (or atom types), e.g.

    Pair Coeffs

    1 lj/cut/coul/cut 1.0 1.0
    ...

    PairIJ Coeffs

    1 1 lj/cut/coul/cut 1.0 1.0
    ...

Note that the pair_coeff command for some potentials such as [pair_style
eam/alloy](pair_eam) includes a mapping specification of elements to all
atom types, which in the hybrid case, can include atom types not
assigned to the *eam/alloy* potential. The NULL keyword is used by many
such potentials (eam/alloy, Tersoff, AIREBO, etc), to denote an atom
type that will be assigned to a different sub-style.

For the *hybrid* style, each atom type pair I,J is assigned to exactly
one sub-style. Just as with a simulation using a single pair style, if
you specify the same atom type pair in a second pair_coeff command, the
previous assignment will be overwritten.

For the *hybrid/overlay* and *hybrid/scaled* styles, each atom type pair
I,J can be assigned to one or more sub-styles. If you specify the same
atom type pair in a second pair_coeff command with a new sub-style, then
the second sub-style is added to the list of potentials that will be
calculated for two interacting atoms of those types. If you specify the
same atom type pair in a second pair_coeff command with a sub-style that
has already been defined for that pair of atoms, then the new pair
coefficients simply override the previous ones, as in the normal usage
of the pair_coeff command. E.g. these two sets of commands are the same:

``` LAMMPS
pair_style lj/cut 2.5
pair_coeff * * 1.0 1.0
pair_coeff 2 2 1.5 0.8

pair_style hybrid/overlay lj/cut 2.5
pair_coeff * * lj/cut 1.0 1.0
pair_coeff 2 2 lj/cut 1.5 0.8
```

Coefficients must be defined for each pair of atoms types via the
[pair_coeff](pair_coeff) command as described above, or in the \"Pair
Coeffs\" or \"PairIJ Coeffs\" section of the data file read by the
[read_data](read_data) command, or by mixing as described below.

For all of the *hybrid*, *hybrid/overlay*, and *hybrid/scaled* styles,
every atom type pair I,J (where I \<= J) must be assigned to at least
one sub-style via the [pair_coeff](pair_coeff) command as in the
examples above, or in the data file read by the [read_data](read_data),
or by mixing as described below. Also all sub-styles must be used at
least once in a [pair_coeff](pair_coeff) command.

:::: warning
::: title
Warning
:::

With hybrid pair styles the use of mixing to generate pair coefficients
is significantly limited compared to the individual pair styles. LAMMPS
**never** performs mixing of parameters from different sub-styles,
**even** if they use the same type of coefficients, e.g. contain a
Lennard-Jones potential variant. Those parameters must be provided
explicitly. Also for *hybrid/overlay* and *hybrid/scaled* mixing is
**only** performed for pairs of atom types for which only a single pair
style is assigned.

Thus it is strongly recommended to provide all mixed terms explicitly.
For non-hybrid styles those could be generated and written out using the
[write_coeff command](write_coeff) and then edited as needed to comply
with the requirements for hybrid styles as explained above.
::::

If you want there to be no interactions between a particular pair of
atom types, you have 3 choices. You can assign the pair of atom types to
some sub-style and use the [neigh_modify exclude type](neigh_modify)
command. You can assign it to some sub-style and set the coefficients so
that there is effectively no interaction (e.g. epsilon = 0.0 in a LJ
potential). Or, for *hybrid*, *hybrid/overlay*, or *hybrid/scaled*
simulations, you can use this form of the pair_coeff command in your
input script or the \"PairIJ Coeffs\" section of your data file:

``` LAMMPS
pair_coeff  2 3  none
```

or this form in the \"Pair Coeffs\" section of the data file:

    3  none

If an assignment to *none* is made in a simulation with the
*hybrid/overlay* or *hybrid/scaled* pair style, it wipes out all
previous assignments of that pair of atom types to sub-styles.

Note that you may need to use an [atom_style](atom_style) hybrid command
in your input script, if atoms in the simulation will need attributes
from several atom styles, due to using multiple pair styles with
different requirements.

------------------------------------------------------------------------

Different force fields (e.g. CHARMM vs. AMBER) may have different rules
for applying exclusions or weights that change the strength of pairwise
non-bonded interactions between pairs of atoms that are also 1-2, 1-3,
and 1-4 neighbors in the molecular bond topology. This is normally a
global setting defined the [special_bonds](special_bonds) command.
However, different weights can be assigned to different hybrid
sub-styles via the [pair_modify special](pair_modify) command. This
allows multiple force fields to be used in a model of a hybrid system,
however, there is no consistent approach to determine parameters
automatically for the interactions **between** atoms of the two force
fields, thus this approach this is only recommended when particles
described by the different force fields do not mix.

Here is an example for combining CHARMM and AMBER: The global *amber*
setting sets the 1-4 interactions to non-zero scaling factors and then
overrides them with 0.0 only for CHARMM:

``` LAMMPS
special_bonds amber
pair_style hybrid lj/charmm/coul/long 8.0 10.0 lj/cut/coul/long 10.0
pair_modify pair lj/charmm/coul/long special lj/coul 0.0 0.0 0.0
```

This input achieves the same effect:

``` LAMMPS
special_bonds 0.0 0.0 0.1
pair_style hybrid lj/charmm/coul/long 8.0 10.0 lj/cut/coul/long 10.0
pair_modify pair lj/cut/coul/long special lj 0.0 0.0 0.5
pair_modify pair lj/cut/coul/long special coul 0.0 0.0 0.83333333
pair_modify pair lj/charmm/coul/long special lj/coul 0.0 0.0 0.0
```

Here is an example for combining Tersoff with OPLS/AA based on a data
file that defines bonds for all atoms where - for the Tersoff part of
the system - the force constants for the bonded interactions have been
set to 0. Note the global settings are effectively *lj/coul 0.0 0.0 0.5*
as required for OPLS/AA:

``` LAMMPS
special_bonds lj/coul 1e-20 1e-20 0.5
pair_style hybrid tersoff lj/cut/coul/long 12.0
pair_modify pair tersoff special lj/coul 1.0 1.0 1.0
```

For use with the various [compute \*/tally](compute_tally) computes, the
[pair_modify compute/tally](pair_modify) command can be used to
selectively turn off processing of the compute tally styles, for
example, if those pair styles (e.g. many-body styles) do not support
this feature.

See the [pair_modify](pair_modify) page for details on the specific
syntax, requirements and restrictions.

------------------------------------------------------------------------

The potential energy contribution to the overall system due to an
individual sub-style can be accessed and output via the [compute
pair](compute_pair) command. Note that in the case of pair style
*hybrid/scaled* this is the **unscaled** potential energy of the
selected sub-style.

------------------------------------------------------------------------

:::: note
::: title
Note
:::

Several of the potentials defined via the pair_style command in LAMMPS
are really many-body potentials, such as Tersoff, AIREBO, MEAM, ReaxFF,
etc. The way to think about using these potentials in a hybrid setting
is as follows.
::::

A subset of atom types is assigned to the many-body potential with a
single [pair_coeff](pair_coeff) command, using \"\* \*\" to include all
types and the NULL keywords described above to exclude specific types
not assigned to that potential. If types 1,3,4 were assigned in that way
(but not type 2), this means that all many-body interactions between all
atoms of types 1,3,4 will be computed by that potential. Pair_style
hybrid allows interactions between type pairs 2-2, 1-2, 2-3, 2-4 to be
specified for computation by other pair styles. You could even add a
second interaction for 1-1 to be computed by another pair style,
assuming pair_style hybrid/overlay is used.

But you should not, as a general rule, attempt to exclude the many-body
interactions for some subset of the type pairs within the set of 1,3,4
interactions, e.g. exclude 1-1 or 1-3 interactions. That is not
conceptually well-defined for many-body interactions, since the
potential will typically calculate energies and foces for small groups
of atoms, e.g. 3 or 4 atoms, using the neighbor lists of the atoms to
find the additional atoms in the group.

However, you can still use the pair_coeff none setting or the
[neigh_modify exclude](neigh_modify) command to exclude certain type
pairs from the neighbor list that will be passed to a many-body
sub-style. This will alter the calculations made by a many-body
potential beyond the specific pairs, since it builds its list of 3-body,
4-body, etc interactions from the pair lists. You will need to think
**carefully** as to whether excluding such pairs produces a physically
meaningful result for your model.

For example, imagine you have two atom types in your model, type 1 for
atoms in one surface, and type 2 for atoms in the other, and you wish to
use a Tersoff potential to compute interactions within each surface, but
not between the surfaces. Then either of these two command sequences
would implement that model:

``` LAMMPS
pair_style hybrid tersoff
pair_coeff * * tersoff SiC.tersoff C C
pair_coeff 1 2 none

pair_style tersoff
pair_coeff * * SiC.tersoff C C
neigh_modify exclude type 1 2
```

Either way, only neighbor lists with 1-1 or 2-2 interactions would be
passed to the Tersoff potential, which means it would compute no 3-body
interactions containing both type 1 and 2 atoms.

Here is another example to use 2 many-body potentials together in an
overlapping manner using hybrid/overlay. Imagine you have CNT (C atoms)
on a Si surface. You want to use Tersoff for Si/Si and Si/C
interactions, and AIREBO for C/C interactions. Si atoms are type 1; C
atoms are type 2. Something like this will work:

``` LAMMPS
pair_style hybrid/overlay tersoff airebo 3.0
pair_coeff * * tersoff SiC.tersoff.custom Si C
pair_coeff * * airebo CH.airebo NULL C
```

Note that to prevent the Tersoff potential from computing C/C
interactions, you would need to **modify** the SiC.tersoff potential
file to turn off C/C interaction, i.e. by setting the appropriate
coefficients to 0.0.

------------------------------------------------------------------------

Styles with a *gpu*, *intel*, *kk*, *omp*, or *opt* suffix are
functionally the same as the corresponding style without the suffix.
They have been optimized to run faster, depending on your available
hardware, as discussed on the [Accelerator packages](Speed_packages)
page. The accelerated styles take the same arguments and should produce
the same results, except for round-off and precision issues.

These accelerated styles are part of the GPU, INTEL, KOKKOS, OPENMP, and
OPT packages, respectively. They are only enabled if LAMMPS was built
with those packages. See the [Build package](Build_package) page for
more info.

You can specify the accelerated styles explicitly in your input script
by including their suffix, or you can use the [-suffix command-line
switch](Run_options) when you invoke LAMMPS, or you can use the
[suffix](suffix) command in your input script.

See the [Accelerator packages](Speed_packages) page for more
instructions on how to use the accelerated styles effectively.

:::: note
::: title
Note
:::

Since the *hybrid*, *hybrid/overlay*, *hybrid/scaled* styles delegate
computation to the individual sub-styles, the suffix versions of the
*hybrid* and *hybrid/overlay* styles are used to propagate the
corresponding suffix to all sub-styles, if those versions exist.
Otherwise the non-accelerated version will be used. The individual
accelerated sub-styles are part of the GPU, KOKKOS, INTEL, OPENMP, and
OPT packages, respectively. They are only enabled if LAMMPS was built
with those packages. See the [Build package](Build_package) page for
more info.
::::

------------------------------------------------------------------------

## Mixing, shift, table, tail correction, restart, rRESPA info

Any pair potential settings made via the [pair_modify](pair_modify)
command are passed along to all sub-styles of the hybrid potential.

For atom type pairs I,J and I != J, if the sub-style assigned to I,I and
J,J is the same, and if the sub-style allows for mixing, then the
coefficients for I,J can be mixed. This means you do not have to specify
a pair_coeff command for I,J since the I,J type pair will be assigned
automatically to the sub-style defined for both I,I and J,J and its
coefficients generated by the mixing rule used by that sub-style. For
the *hybrid/overlay* and *hybrid/scaled* style, there is an additional
requirement that both the I,I and J,J pairs are assigned to a single
sub-style. If this requirement is not met, no I,J coeffs will be
generated, even if the sub-styles support mixing, and I,J pair
coefficients must be explicitly defined.

See the [pair_modify](pair_modify) command for details of mixing rules.
See the See the page for the sub-style to see if allows for mixing.

The hybrid pair styles supports the [pair_modify](pair_modify) shift,
table, and tail options for an I,J pair interaction, if the associated
sub-style supports it.

For the hybrid pair styles, the list of sub-styles and their respective
settings are written to [binary restart files](restart), so a
[pair_style](pair_style) command does not need to specified in an input
script that reads a restart file. However, the coefficient information
is not stored in the restart file. Thus, pair_coeff commands need to be
re-specified in the restart input script. For pair style *hybrid/scaled*
also the names of any variables used as scale factors are restored, but
not the variables themselves, so those may need to be redefined when
continuing from a restart.

These pair styles support the use of the *inner*, *middle*, and *outer*
keywords of the [run_style respa](run_style) command, if their
sub-styles do.

## Restrictions

When using a long-range Coulombic solver (via the
[kspace_style](kspace_style) command) with a hybrid pair_style, one or
more sub-styles will be of the \"long\" variety, e.g. *lj/cut/coul/long*
or *buck/coul/long*. You must ensure that the short-range Coulombic
cutoff used by each of these long pair styles is the same or else LAMMPS
will generate an error.

Pair style *hybrid/scaled* currently only works for non-accelerated pair
styles and pair styles from the OPT package.

When using pair styles from the GPU package they must not be listed
multiple times. LAMMPS will detect this and abort.

## Related commands

[pair_coeff](pair_coeff)

## Default

none