# fix pour command

## Syntax

    fix ID group-ID pour N type seed keyword values ...

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

-   pour = style name of this fix command

-   N = \# of particles to insert

-   type = atom type to assign to inserted particles (offset for
    molecule insertion)

-   seed = random \# seed (positive integer)

-   one or more keyword/value pairs may be appended to args

-   keyword = *region* or *diam* or *id* or *vol* or *rate* or *dens* or
    *vel* or *mol* or *molfrac* or *rigid* or *shake* or *ignore*

        *region* value = region-ID
          region-ID = ID of region to use as insertion volume
        *diam* values = dstyle args
          dstyle = *one* or *range* or *poly*
            *one* args = D
              D = single diameter for inserted particles (distance units)
            *range* args = Dlo Dhi
              Dlo,Dhi = range of diameters for inserted particles (distance units)
            *poly* args = Npoly D1 P1 D2 P2 ...
              Npoly = # of (D,P) pairs
              D1,D2,... = diameter for subset of inserted particles (distance units)
              P1,P2,... = percentage of inserted particles with this diameter (0-1)
        *id* values = idflag
          idflag = *max* or *next* = how to choose IDs for inserted particles and molecules
        *vol* values = fraction Nattempt
          fraction = desired volume fraction for filling insertion volume
          Nattempt = max # of insertion attempts per particle
        *rate* value = V
          V = z velocity (3d) or y velocity (2d) at which
              insertion volume moves (velocity units)
        *dens* values = Rholo Rhohi
          Rholo,Rhohi = range of densities for inserted particles (mass/volume units)
        *vel* values (3d) = vxlo vxhi vylo vyhi vz
        *vel* values (2d) = vxlo vxhi vy
          vxlo,vxhi = range of x velocities for inserted particles (velocity units)
          vylo,vyhi = range of y velocities for inserted particles (velocity units)
          vz = z velocity (3d) assigned to inserted particles (velocity units)
          vy = y velocity (2d) assigned to inserted particles (velocity units)
        *mol* value = template-ID
          template-ID = ID of molecule template specified in a separate `molecule <molecule>`__ command
        *molfrac* values = f1 f2 ... fN
          f1 to fN = relative probability of creating each of N molecules in template-ID
        *rigid* value = fix-ID
          fix-ID = ID of `fix rigid/small <fix_rigid>`__ command
        *shake* value = fix-ID
          fix-ID = ID of `fix shake <fix_shake>`__ command
        *ignore* value = none
          skip any line or triangle particles when detecting possible
            overlaps with inserted particles

## Examples

``` LAMMPS
fix 3 all pour 1000 2 29494 region myblock
fix 2 all pour 10000 1 19985583 region disk vol 0.33 100 rate 1.0 diam range 0.9 1.1
fix 2 all pour 10000 1 19985583 region disk diam poly 2 0.7 0.4 1.5 0.6
fix ins all pour 500 1 4767548 vol 0.8 10 region slab mol object rigid myRigid
```

## Description

Insert finite-size particles or molecules into the simulation box every
few timesteps within a specified region until N particles or molecules
have been inserted. This is typically used to model the pouring of
granular particles into a container under the influence of gravity. For
the remainder of this doc page, a single inserted atom or molecule is
referred to as a \"particle\".

If inserted particles are individual atoms, they are assigned the
specified atom type. If they are molecules, the type of each atom in the
inserted molecule is specified in the file read by the
[molecule](molecule) command, and those values are added to the
specified atom type. E.g. if the file specifies atom types 1,2,3, and
those are the atom types you want for inserted molecules, then specify
*type* = 0. If you specify *type* = 2, the in the inserted molecule will
have atom types 3,4,5.

All atoms in the inserted particle are assigned to two groups: the
default group \"all\" and the group specified in the fix pour command
(which can also be \"all\").

This command must use the *region* keyword to define an insertion
volume. The specified region must have been previously defined with a
[region](region) command. It must be of type *block* or a z-axis
*cylinder* and must be defined with side = *in*. The cylinder style of
region can only be used with 3d simulations.

Individual atoms are inserted, unless the *mol* keyword is used. It
specifies a *template-ID* previously defined using the
[molecule](molecule) command, which reads a file that defines the
molecule. The coordinates, atom types, center-of-mass, moments of
inertia, etc, as well as any bond/angle/etc and special neighbor
information for the molecule can be specified in the molecule file. See
the [molecule](molecule) command for details. The only settings required
to be in this file are the coordinates and types of atoms in the
molecule.

If the molecule template contains more than one molecule, the relative
probability of depositing each molecule can be specified by the
*molfrac* keyword. N relative probabilities, each from 0.0 to 1.0, are
specified, where N is the number of molecules in the template. Each time
a molecule is inserted, a random number is used to sample from the list
of relative probabilities. The N values must sum to 1.0.

If you wish to insert molecules via the *mol* keyword, that will be
treated as rigid bodies, use the *rigid* keyword, specifying as its
value the ID of a separate [fix rigid/small](fix_rigid) command which
also appears in your input script.

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

If you wish the new rigid molecules (and other rigid molecules) to be
thermostatted correctly via [fix rigid/small/nvt](fix_rigid) or [fix
rigid/small/npt](fix_rigid), then you need to use the \"fix_modify
dynamic/dof yes\" command for the rigid fix. This is to inform that fix
that the molecule count will vary dynamically.
::::

If you wish to insert molecules via the *mol* keyword, that will have
their bonds or angles constrained via SHAKE, use the *shake* keyword,
specifying as its value the ID of a separate [fix shake](fix_shake)
command which also appears in your input script.

Each timestep particles are inserted, they are placed randomly inside
the insertion volume so as to mimic a stream of poured particles. If
they are molecules they are also oriented randomly. Each atom in the
particle is tested for overlaps with existing particles, including
effects due to periodic boundary conditions if applicable. If an overlap
is detected, another random insertion attempt is made; see the *vol*
keyword discussion below. The larger the volume of the insertion region,
the more particles that can be inserted at any one timestep. Particles
are inserted again after enough time has elapsed that the previously
inserted particles fall out of the insertion volume under the influence
of gravity. Insertions continue every so many timesteps until the
desired \# of particles has been inserted.

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

If you are monitoring the temperature of a system where the particle
count is changing due to adding particles, you typically should use the
[compute_modify dynamic yes](compute_modify) command for the temperature
compute you are using.
::::

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

All other keywords are optional with defaults as shown below.

The *diam* option is only used when inserting atoms and specifies the
diameters of inserted particles. There are 3 styles: *one*, *range*, or
*poly*. For *one*, all particles will have diameter *D*. For *range*,
the diameter of each particle will be chosen randomly and uniformly
between the specified *Dlo* and *Dhi* bounds. For *poly*, a series of
*Npoly* diameters is specified. For each diameter a percentage value
from 0.0 to 1.0 is also specified. The *Npoly* percentages must sum to
1.0. For the example shown above with \"diam 2 0.7 0.4 1.5 0.6\", all
inserted particles will have a diameter of 0.7 or 1.5. 40% of the
particles will be small; 60% will be large.

Note that for molecule insertion, the diameters of individual atoms in
the molecule can be specified in the file read by the
[molecule](molecule) command. If not specified, the diameter of each
atom in the molecule has a default diameter of 1.0.

The *id* option has two settings which are used to determine the atom or
molecule IDs to assign to inserted particles/molecules. In both cases a
check is done of the current system to find the maximum current atom and
molecule ID of any existing particle. Newly inserted particles and
molecules are assigned IDs that increment those max values. For the
*max* setting, which is the default, this check is done at every
insertion step, which allows for particles to leave the system, and
their IDs to potentially be re-used. For the *next* setting this check
is done only once when the fix is specified, which can be more efficient
if you are sure particles will not be added in some other way.

The *vol* option specifies what volume fraction of the insertion volume
will be filled with particles. For particles with a size specified by
the *diam range* keyword, they are assumed to all be of maximum diameter
*Dhi* for purposes of computing their contribution to the volume
fraction.

The higher the volume fraction value, the more particles are inserted
each timestep. Since inserted particles cannot overlap, the maximum
volume fraction should be no higher than about 0.6. Each timestep
particles are inserted, LAMMPS will make up to a total of M tries to
insert the new particles without overlaps, where M = \# of inserted
particles \* Nattempt. If LAMMPS is unsuccessful at completing all
insertions, it prints a warning.

The *dens* and *vel* options enable inserted particles to have a range
of densities or xy velocities. The specific values for a particular
inserted particle will be chosen randomly and uniformly between the
specified bounds. Internally, the density value for a particle is
converted to a mass, based on the radius (volume) of the particle. The
*vz* or *vy* value for option *vel* assigns a z-velocity (3d) or
y-velocity (2d) to each inserted particle.

The *rate* option moves the insertion volume in the z direction (3d) or
y direction (2d). This enables pouring particles from a successively
higher height over time.

The *ignore* option is useful when running a simulation that used line
segment (2d) or triangle (3d) particles, typically to define boundaries
for spherical granular particles to interact with. See the [atom_style
line or tri](atom_style) command for details. Lines and triangles store
their size, and if the size is large it may overlap (in a spherical
sense) with the insertion region, even if the line/triangle is oriented
such that there is no actual overlap. This can prevent particles from
being inserted. The *ignore* keyword causes the overlap check to skip
any line or triangle particles. Obviously you should only use it if
there is in fact no overlap of the line or triangle particles with the
insertion region.

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

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

No information about this fix is written to [binary restart
files](restart). This means you must be careful when restarting a
pouring simulation, when the restart file was written in the middle of
the pouring operation. Specifically, you should use a new fix pour
command in the input script for the restarted simulation that continues
the operation. You will need to adjust the arguments of the original fix
pour command to do this.

Also note that because the state of the random number generator is not
saved in restart files, you cannot do \"exact\" restarts with this fix,
where the simulation continues on the same as if no restart had taken
place. However, in a statistical sense, a restarted simulation should
produce the same behavior if you adjust the fix pour parameters
appropriately.

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

This fix is part of the GRANULAR package. It is only enabled if LAMMPS
was built with that package. See the [Build package](Build_package) page
for more info.

For 3d simulations, a gravity fix in the -z direction must be defined
for use in conjunction with this fix. For 2d simulations, gravity must
be defined in the -y direction.

The specified insertion region cannot be a \"dynamic\" region, as
defined by the [region](region) command.

## Related commands

[fix deposit](fix_deposit), [fix gravity](fix_gravity), [region](region)

## Default

Insertions are performed for individual particles, i.e. no *mol* setting
is defined. If the *mol* keyword is used, the default for *molfrac* is
an equal probabilities for all molecules in the template. Additional
option defaults are diam = one 1.0, dens = 1.0 1.0, vol = 0.25 50, rate
= 0.0, vel = 0.0 0.0 0.0 0.0 0.0 (for 3d), vel = 0.0 0.0 0.0 (for 2d),
and id = max.