# fix property/atom command

Accelerator Variants: *property/atom/kk*

## Syntax

    fix ID group-ID property/atom name1 name2 ... keyword value ...

-   ID, group-ID are documented in [fix](fix) command

-   property/atom = style name of this fix command

-   name1,name2,\... = *mol* or *q* or *rmass* or i_name or d_name or
    i2_name or d2_name

        *mol* = molecule IDs
        *q* = charge
        *rmass* = per-atom mass
        i_name = new integer vector referenced by name
        d_name = new floating-point vector referenced by name
        i2_name = new integer array referenced by name
           i2_name arg = N = number of columns in the array
        d2_name = new floating-point array referenced by name
           d2_name arg = N = number of columns in the array

-   zero of more keyword/value pairs may be appended

-   keyword = *ghost*

        *ghost* value = *no* or *yes* for whether ghost atom info in communicated

## Examples

``` LAMMPS
fix 1 all property/atom mol
fix 1 all property/atom i_myflag1 i_myflag2
fix 1 all property/atom d2_sxyz 3 ghost yes
```

## Description

Create one or more additional per-atom vectors or arrays to store
information about atoms and to use during a simulation. The specified
*group-ID* is ignored by this fix.

The atom style used for a simulation defines a set of per-atom
properties, as explained on the [atom_style](atom_style) and
[read_data](read_data) doc pages. The latter command defines these
properties for each atom in the system when a data file is read. This
fix augments the set of per-atom properties with new custom ones. This
can be useful in several scenarios.

If the atom style does not define molecule IDs, per-atom charge, or
per-atom mass, they can be added using the *mol*, *q* or *rmass*
keywords. This could be useful to define \"molecules\" to use as rigid
bodies with the [fix rigid](fix_rigid) command, or to carry around an
extra flag with atoms (stored as a molecule ID) that can be used by
various commands like [compute chunk/atom](compute_chunk_atom) to group
atoms without having to use the group command (which is limited to a
total of 32 groups including *all*).

Another application is to use the *rmass* flag in order to have per-atom
masses instead of per-type masses. This could be used to study isotope
effects with partial isotope substitution. [See below](isotopes) for an
example of simulating a mixture of light and heavy water with the TIP4P
water potential.

An alternative to using fix *property/atom* for these examples is to use
an atom style that does define molecule IDs or charge or per-atom mass
(indirectly via diameter and density) or to use a hybrid atom style that
combines two or more atom styles to provide the union of all their atom
properties. However, this has two practical drawbacks: first, it
typically necessitates changing the format of the Atoms section in the
data file and second, it may define additional properties that are not
needed such as bond lists, which incurs some overhead when there are no
bonds.

In the future, we may add additional existing per-atom properties to fix
property/atom, similar to *mol*, *q* or *rmass*, which \"turn-on\"
specific properties defined by some atom styles, so they can be easily
used by atom styles that do not define them.

More generally, the *i_name* and *d_name* options allow one or more new
custom per-atom vectors to be defined. Likewise the *i2_name* and
*d2_name* options allow one or more custom per-atom arrays to be
defined. The *i2_name* and *d2_name* options take an argument *N* which
specifies the number of columns in the per-atom array, i.e. the number
of attributes associated with each atom. *N* \>= 1 is required.

Each name must be unique and can use alphanumeric or underscore
characters. These vectors and arrays can store whatever values you
decide are useful in your simulation. As explained below there are
several ways to initialize, access, and output these values, via input
script commands, data files, and in new code you add to LAMMPS.

This is effectively a simple way to add per-atom properties to a model
without needing to write code for a new [atom style](atom_style) that
defines the properties. Note however that implementing a new atom style
allows new atom properties to be more tightly and seamlessly integrated
with the rest of the code.

The new atom properties encode values that migrate with atoms to new
processors and are written to restart files. If you want the new
properties to also be defined for ghost atoms, then use the *ghost*
keyword with a value of *yes*. This will invoke extra communication when
ghost atoms are created (at every re-neighboring) to ensure the new
properties are also defined for the ghost atoms.

::: {.admonition .note}
Properties on ghost atoms

If you use the *mol*, *q* or *rmass* names, you most likely want to set
*ghost* yes, since these properties are stored with ghost atoms if you
use an [atom_style](atom_style) that defines them. Many LAMMPS
operations that use molecule IDs or charge, such as neighbor lists and
pair styles, will expect ghost atoms to have these values. LAMMPS will
issue a warning it you define those vectors but do not set *ghost* yes.
:::

::: {.admonition .note}
Limitations on ghost atom properties

The specified properties for ghost atoms are not updated every timestep,
but only once every few steps when neighbor lists are re-built. Thus the
*ghost* keyword is suitable for static properties, like molecule IDs,
but not for dynamic properties that change every step. For the latter,
the code you add to LAMMPS to change the properties will also need to
communicate their new values to/from ghost atoms, an operation that can
be invoked from within a [pair style](pair_style) or [fix](fix) or
[compute](compute) that you write.
:::

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

This fix is one of a small number that can be defined in an input script
before the simulation box is created or atoms are defined. This is so it
can be used with the [read_data](read_data) command as described next.

Per-atom properties that are defined by the [atom style](atom_style) are
initialized when atoms are created, e.g. by the [read_data](read_data)
or [create_atoms](create_atoms) commands. The per-atom properties
defined by this fix are not. So you need to initialize them explicitly.
One way to do this is [read_data](read_data) command, using its *fix*
keyword and passing it the fix-ID of this fix.

Thus these commands:

``` LAMMPS
fix prop all property/atom mol d_flag
read_data data.txt fix prop NULL Molecules
```

would allow a data file to have a section like this:

    Molecules

    1 4 1.5
    2 4 3.0
    3 10 1.0
    4 10 1.0
    5 10 1.0
    ...
    N 763 4.5

where N is the number of atoms, the first field on each line is the
atom-ID, the next two are a molecule-ID and a floating point value that
will be stored in a new property called \"flag\". If a per-atom array
was specified in the fix property/atom command then the *N* values for
that array must be specified consecutively for that property on each
line. Note that the order of values on each line corresponds to the
order of custom names in the fix property/atom command.

Note that the the lines of per-atom properties can be listed in any
order. Also note that all the per-atom properties specified by the fix
ID (prop in this case) must be included on each line in the specified
data file section (Molecules in this case).

Another way of initializing the new properties is via the [set](set)
command. For example, if you wanted molecules defined for every set of
10 atoms, based on their atom-IDs, these commands could be used:

``` LAMMPS
fix prop all property/atom mol
variable cluster atom ((id-1)/10)+1
set atom * mol v_cluster
```

The [atom-style variable](variable) will create values for atoms with
IDs 31,32,33,\...40 that are 4.0,4.1,4.2,\...,4.9. When the [set](set)
commands assigns them to the molecule ID for each atom, they will be
truncated to an integer value, so atoms 31-40 will all be assigned a
molecule ID of 4.

Note that [atomfile-style variables](variable) can also be used in place
of atom-style variables, which means in this case that the molecule IDs
could be read-in from a separate file and assigned by the [set](set)
command. This allows you to initialize new per-atom properties in a
completely general fashion.

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

For new atom properties specified as *i_name*, *d_name*, *i2_name*, or
*d2_name*, the [dump custom](dump) and [compute
property/atom](compute_property_atom) commands can access their values.
This means that the values can be used accessed by fixes like [fix
ave/atom](fix_ave_atom), accessed by other computes like [compute
reduce](compute_reduce), or used in [atom-style variables](variable).

For example, these commands will output both the instantaneous and
time-averaged values of two new properties to a custom dump file:

``` LAMMPS
fix myprops all property/atom i_flag1 d_flag2
compute 1 all property/atom i_flag1 d_flag2
fix 1 all ave/atom 10 10 100 c_1[1] c_1[2]
dump 1 all custom 100 tmp.dump id x y z i_flag1 d_flag2 f_1[1] f_1[2]
```

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

If you wish to add new [pair styles](pair_style), [fixes](fix), or
[computes](compute) that use the per-atom properties defined by this
fix, see the [Modify atom](Modify_atom) doc page which has details on
how the custom properties of this fix can be accessed from added
classes.

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

::: {#isotopes}
Here is an example of using per-atom masses with TIP4P water to study
isotope effects. When setting up simulations with the [TIP4P pair
styles](Howto_tip4p) for water, you have to provide exactly one atom
type each to identify the water oxygen and hydrogen atoms. Since the
atom mass is normally tied to the atom type, this makes it impossible to
study multiple isotopes in the same simulation. With *fix property/atom
rmass* however, the per-type masses are replaced by per-atom masses.
Asumming you have a working input deck for regular TIP4P water, where
water oxygen is atom type 1 and water hydrogen is atom type 2, the
following lines of input script convert this to using per-atom masses:
:::

``` LAMMPS
fix Isotopes all property/atom rmass ghost yes
set type 1 mass 15.9994
set type 2 mass 1.008
```

When writing out the system data with the [write_data](write_data)
command, there will be a new section named with the fix-ID (i.e.
*Isotopes* in this case). Alternatively, you can take an existing data
file and just add this *Isotopes* section with one line per atom
containing atom-ID and mass. Either way, the extended data file can be
read back with:

``` LAMMPS
fix Isotopes all property/atom rmass ghost yes
read_data tip4p-isotopes.data fix Isotopes NULL Isotopes
```

Please note that the first *Isotopes* refers to the fix-ID and the
second to the name of the section. The following input script code will
now change the first 100 water molecules in this example to heavy water:

``` LAMMPS
group hwat id 2:300:3
group hwat id 3:300:3
set group hwat mass 2.0141018
```

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

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.

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

## Restart, fix_modify, output, run start/stop, minimize info

This fix writes the per-atom values it stores to [binary restart
files](restart), so that the values can be restored when a simulation is
restarted. See the [read_restart](read_restart) command for info on how
to re-specify a fix in an input script that reads a restart file, so
that the operation of the fix continues in an uninterrupted fashion.

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

When reading data from a restart file, this fix command has to be
specified **after** the *read_restart* command and **exactly** the same
was in the input script that created the restart file. LAMMPS will only
check whether a fix is of the same style and has the same fix ID and in
case of a match will then try to initialize the fix with the data stored
in the binary restart file. If the names and associated date types in
the new fix property/atom command do not match the old one exactly, data
can be corrupted or LAMMPS may crash. If the fix is specified **before**
the *read_restart* command its data will not be restored.
::::

None of the [fix_modify](fix_modify) options are relevant to this fix.
No global or per-atom quantities are stored by this fix for access by
various [output commands](Howto_output). No parameter of this fix can be
used with the *start/stop* keywords of the [run](run) command. This fix
is not invoked during [energy minimization](minimize).

## Restrictions

> none

## Related commands

[read_data](read_data), [set](set), [compute
property/atom](compute_property_atom)

## Default

The default keyword value is ghost = no.