# fix deform command

Accelerator Variants: *deform/kk*

## Syntax

    fix ID group-ID deform N parameter args ... keyword value ...

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

-   deform = style name of this fix command

-   N = perform box deformation every this many timesteps

-   one or more parameter/arg pairs may be appended

        parameter = *x* or *y* or *z* or *xy* or *xz* or *yz*
          *x*, *y*, *z* args = style value(s)
            style = *final* or *delta* or *scale* or *vel* or *erate* or *trate* or *volume* or *wiggle* or *variable*
              *final* values = lo hi
                lo hi = box boundaries at end of run (distance units)
              *delta* values = dlo dhi
                dlo dhi = change in box boundaries at end of run (distance units)
              *scale* values = factor
                factor = multiplicative factor for change in box length at end of run
              *vel* value = V
                V = change box length at this velocity (distance/time units),
                    effectively an engineering strain rate
              *erate* value = R
                R = engineering strain rate (1/time units)
              *trate* value = R
                R = true strain rate (1/time units)
              *volume* value = none = adjust this dim to preserve volume of system
              *wiggle* values = A Tp
                A = amplitude of oscillation (distance units)
                Tp = period of oscillation (time units)
              *variable* values = v_name1 v_name2
                v_name1 = variable with name1 for box length change as function of time
                v_name2 = variable with name2 for change rate as function of time
          *xy*, *xz*, *yz* args = style value
            style = *final* or *delta* or *vel* or *erate* or *trate* or *wiggle*
              *final* value = tilt
                tilt = tilt factor at end of run (distance units)
              *delta* value = dtilt
                dtilt = change in tilt factor at end of run (distance units)
              *vel* value = V
                V = change tilt factor at this velocity (distance/time units),
                    effectively an engineering shear strain rate
              *erate* value = R
                R = engineering shear strain rate (1/time units)
              *trate* value = R
                R = true shear strain rate (1/time units)
              *wiggle* values = A Tp
                A = amplitude of oscillation (distance units)
                Tp = period of oscillation (time units)
              *variable* values = v_name1 v_name2
                v_name1 = variable with name1 for tilt change as function of time
                v_name2 = variable with name2 for change rate as function of time

-   zero or more keyword/value pairs may be appended

-   keyword = *remap* or *flip* or *units*

        *remap* value = *x* or *v* or *none*
          x = remap coords of atoms in group into deforming box
          v = remap velocities of atoms in group when they cross periodic boundaries
          none = no remapping of x or v
        *flip* value = *yes* or *no*
          allow or disallow box flips when it becomes highly skewed
        *units* value = *lattice* or *box*
          lattice = distances are defined in lattice units
          box = distances are defined in simulation box units

## Examples

``` LAMMPS
fix 1 all deform 1 x final 0.0 9.0 z final 0.0 5.0 units box
fix 1 all deform 1 x trate 0.1 y volume z volume
fix 1 all deform 1 xy erate 0.001 remap v
fix 1 all deform 10 y delta -0.5 0.5 xz vel 1.0
```

## Description

Change the volume and/or shape of the simulation box during a dynamics
run. Orthogonal simulation boxes have 3 adjustable parameters (x,y,z).
Triclinic (non-orthogonal) simulation boxes have 6 adjustable parameters
(x,y,z,xy,xz,yz). Any or all of them can be adjusted independently and
simultaneously by this command.

This fix can be used to perform non-equilibrium MD (NEMD) simulations of
a continuously strained system. See the [fix nvt/sllod](fix_nvt_sllod)
and [compute temp/deform](compute_temp_deform) commands for more
details. Note that simulation of a continuously extended system
(extensional flow) can be modeled using the [UEF package](PKG-UEF) and
its [fix commands](fix_nh_uef).

For the *x*, *y*, *z* parameters, the associated dimension cannot be
shrink-wrapped. For the *xy*, *yz*, *xz* parameters, the associated
second dimension cannot be shrink-wrapped. Dimensions not varied by this
command can be periodic or non-periodic. Dimensions corresponding to
unspecified parameters can also be controlled by a [fix npt](fix_nh) or
[fix nph](fix_nh) command.

The size and shape of the simulation box at the beginning of the
simulation run were either specified by the [create_box](create_box) or
[read_data](read_data) or [read_restart](read_restart) command used to
setup the simulation initially if it is the first run, or they are the
values from the end of the previous run. The [create_box](create_box),
[read data](read_data), and [read_restart](read_restart) commands
specify whether the simulation box is orthogonal or non-orthogonal
(triclinic) and explain the meaning of the xy,xz,yz tilt factors. If fix
deform changes the xy,xz,yz tilt factors, then the simulation box must
be triclinic, even if its initial tilt factors are 0.0.

As described below, the desired simulation box size and shape at the end
of the run are determined by the parameters of the fix deform command.
Every Nth timestep during the run, the simulation box is expanded,
contracted, or tilted to ramped values between the initial and final
values.

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

For the *x*, *y*, and *z* parameters, this is the meaning of their
styles and values.

The *final*, *delta*, *scale*, *vel*, and *erate* styles all change the
specified dimension of the box via \"constant displacement\" which is
effectively a \"constant engineering strain rate\". This means the box
dimension changes linearly with time from its initial to final value.

For style *final*, the final lo and hi box boundaries of a dimension are
specified. The values can be in lattice or box distance units. See the
discussion of the units keyword below.

For style *delta*, plus or minus changes in the lo/hi box boundaries of
a dimension are specified. The values can be in lattice or box distance
units. See the discussion of the units keyword below.

For style *scale*, a multiplicative factor to apply to the box length of
a dimension is specified. For example, if the initial box length is 10,
and the factor is 1.1, then the final box length will be 11. A factor
less than 1.0 means compression.

For style *vel*, a velocity at which the box length changes is specified
in units of distance/time. This is effectively a \"constant engineering
strain rate\", where rate = V/L0 and L0 is the initial box length. The
distance can be in lattice or box distance units. See the discussion of
the units keyword below. For example, if the initial box length is 100
Angstroms, and V is 10 Angstroms/ps, then after 10 ps, the box length
will have doubled. After 20 ps, it will have tripled.

The *erate* style changes a dimension of the box at a \"constant
engineering strain rate\". The units of the specified strain rate are
1/time. See the [units](units) command for the time units associated
with different choices of simulation units, e.g. picoseconds for
\"metal\" units). Tensile strain is unitless and is defined as delta/L0,
where L0 is the original box length and delta is the change relative to
the original length. The box length L as a function of time will change
as

    L(t) = L0 (1 + erate\*dt)

where dt is the elapsed time (in time units). Thus if *erate* R is
specified as 0.1 and time units are picoseconds, this means the box
length will increase by 10% of its original length every picosecond.
I.e. strain after 1 ps = 0.1, strain after 2 ps = 0.2, etc. R = -0.01
means the box length will shrink by 1% of its original length every
picosecond. Note that for an \"engineering\" rate the change is based on
the original box length, so running with R = 1 for 10 picoseconds
expands the box length by a factor of 11 (strain of 10), which is
different that what the *trate* style would induce.

The *trate* style changes a dimension of the box at a \"constant true
strain rate\". Note that this is not an \"engineering strain rate\", as
the other styles are. Rather, for a \"true\" rate, the rate of change is
constant, which means the box dimension changes non-linearly with time
from its initial to final value. The units of the specified strain rate
are 1/time. See the [units](units) command for the time units associated
with different choices of simulation units, e.g. picoseconds for
\"metal\" units). Tensile strain is unitless and is defined as delta/L0,
where L0 is the original box length and delta is the change relative to
the original length.

The box length L as a function of time will change as

    L(t) = L0 exp(trate\*dt)

where dt is the elapsed time (in time units). Thus if *trate* R is
specified as ln(1.1) and time units are picoseconds, this means the box
length will increase by 10% of its current (not original) length every
picosecond. I.e. strain after 1 ps = 0.1, strain after 2 ps = 0.21, etc.
R = ln(2) or ln(3) means the box length will double or triple every
picosecond. R = ln(0.99) means the box length will shrink by 1% of its
current length every picosecond. Note that for a \"true\" rate the
change is continuous and based on the current length, so running with R
= ln(2) for 10 picoseconds does not expand the box length by a factor of
11 as it would with *erate*, but by a factor of 1024 since the box
length will double every picosecond.

Note that to change the volume (or cross-sectional area) of the
simulation box at a constant rate, you can change multiple dimensions
via *erate* or *trate*. E.g. to double the box volume in a picosecond
picosecond, you could set \"x erate M\", \"y erate M\", \"z erate M\",
with M = pow(2,1/3) - 1 = 0.26, since if each box dimension grows by
26%, the box volume doubles. Or you could set \"x trate M\", \"y trate
M\", \"z trate M\", with M = ln(1.26) = 0.231, and the box volume would
double every picosecond.

The *volume* style changes the specified dimension in such a way that
the box volume remains constant while other box dimensions are changed
explicitly via the styles discussed above. For example, \"x scale 1.1 y
scale 1.1 z volume\" will shrink the z box length as the x,y box lengths
increase, to keep the volume constant (product of x,y,z lengths). If \"x
scale 1.1 z volume\" is specified and parameter *y* is unspecified, then
the z box length will shrink as x increases to keep the product of x,z
lengths constant. If \"x scale 1.1 y volume z volume\" is specified,
then both the y,z box lengths will shrink as x increases to keep the
volume constant (product of x,y,z lengths). In this case, the y,z box
lengths shrink so as to keep their relative aspect ratio constant.

For solids or liquids, note that when one dimension of the box is
expanded via fix deform (i.e. tensile strain), it may be physically
undesirable to hold the other 2 box lengths constant (unspecified by fix
deform) since that implies a density change. Using the *volume* style
for those 2 dimensions to keep the box volume constant may make more
physical sense, but may also not be correct for materials and potentials
whose Poisson ratio is not 0.5. An alternative is to use [fix npt
aniso](fix_nh) with zero applied pressure on those 2 dimensions, so that
they respond to the tensile strain dynamically.

The *wiggle* style oscillates the specified box length dimension
sinusoidally with the specified amplitude and period. I.e. the box
length L as a function of time is given by

    L(t) = L0 + A sin(2\*pi t/Tp)

where L0 is its initial length. If the amplitude A is a positive number
the box initially expands, then contracts, etc. If A is negative then
the box initially contracts, then expands, etc. The amplitude can be in
lattice or box distance units. See the discussion of the units keyword
below.

The *variable* style changes the specified box length dimension by
evaluating a variable, which presumably is a function of time. The
variable with *name1* must be an [equal-style variable](variable) and
should calculate a change in box length in units of distance. Note that
this distance is in box units, not lattice units; see the discussion of
the *units* keyword below. The formula associated with variable *name1*
can reference the current timestep. Note that it should return the
\"change\" in box length, not the absolute box length. This means it
should evaluate to 0.0 when invoked on the initial timestep of the run
following the definition of fix deform. It should evaluate to a value \>
0.0 to dilate the box at future times, or a value \< 0.0 to compress the
box.

The variable *name2* must also be an [equal-style variable](variable)
and should calculate the rate of box length change, in units of
distance/time, i.e. the time-derivative of the *name1* variable. This
quantity is used internally by LAMMPS to reset atom velocities when they
cross periodic boundaries. It is computed internally for the other
styles, but you must provide it when using an arbitrary variable.

Here is an example of using the *variable* style to perform the same box
deformation as the *wiggle* style formula listed above, where we assume
that the current timestep = 0.

``` LAMMPS
variable A equal 5.0
variable Tp equal 10.0
variable displace equal "v_A * sin(2*PI * step*dt/v_Tp)"
variable rate equal "2*PI*v_A/v_Tp * cos(2*PI * step*dt/v_Tp)"
fix 2 all deform 1 x variable v_displace v_rate remap v
```

For the *scale*, *vel*, *erate*, *trate*, *volume*, *wiggle*, and
*variable* styles, the box length is expanded or compressed around its
mid point.

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

For the *xy*, *xz*, and *yz* parameters, this is the meaning of their
styles and values. Note that changing the tilt factors of a triclinic
box does not change its volume.

The *final*, *delta*, *vel*, and *erate* styles all change the shear
strain at a \"constant engineering shear strain rate\". This means the
tilt factor changes linearly with time from its initial to final value.

For style *final*, the final tilt factor is specified. The value can be
in lattice or box distance units. See the discussion of the units
keyword below.

For style *delta*, a plus or minus change in the tilt factor is
specified. The value can be in lattice or box distance units. See the
discussion of the units keyword below.

For style *vel*, a velocity at which the tilt factor changes is
specified in units of distance/time. This is effectively an
\"engineering shear strain rate\", where rate = V/L0 and L0 is the
initial box length perpendicular to the direction of shear. The distance
can be in lattice or box distance units. See the discussion of the units
keyword below. For example, if the initial tilt factor is 5 Angstroms,
and the V is 10 Angstroms/ps, then after 1 ps, the tilt factor will be
15 Angstroms. After 2 ps, it will be 25 Angstroms.

The *erate* style changes a tilt factor at a \"constant engineering
shear strain rate\". The units of the specified shear strain rate are
1/time. See the [units](units) command for the time units associated
with different choices of simulation units, e.g. picoseconds for
\"metal\" units). Shear strain is unitless and is defined as
offset/length, where length is the box length perpendicular to the shear
direction (e.g. y box length for xy deformation) and offset is the
displacement distance in the shear direction (e.g. x direction for xy
deformation) from the unstrained orientation.

The tilt factor T as a function of time will change as

    T(t) = T0 + L0\*erate\*dt

where T0 is the initial tilt factor, L0 is the original length of the
box perpendicular to the shear direction (e.g. y box length for xy
deformation), and dt is the elapsed time (in time units). Thus if
*erate* R is specified as 0.1 and time units are picoseconds, this means
the shear strain will increase by 0.1 every picosecond. I.e. if the xy
shear strain was initially 0.0, then strain after 1 ps = 0.1, strain
after 2 ps = 0.2, etc. Thus the tilt factor would be 0.0 at time 0,
0.1\*ybox at 1 ps, 0.2\*ybox at 2 ps, etc, where ybox is the original y
box length. R = 1 or 2 means the tilt factor will increase by 1 or 2
every picosecond. R = -0.01 means a decrease in shear strain by 0.01
every picosecond.

The *trate* style changes a tilt factor at a \"constant true shear
strain rate\". Note that this is not an \"engineering shear strain
rate\", as the other styles are. Rather, for a \"true\" rate, the rate
of change is constant, which means the tilt factor changes non-linearly
with time from its initial to final value. The units of the specified
shear strain rate are 1/time. See the [units](units) command for the
time units associated with different choices of simulation units, e.g.
picoseconds for \"metal\" units). Shear strain is unitless and is
defined as offset/length, where length is the box length perpendicular
to the shear direction (e.g. y box length for xy deformation) and offset
is the displacement distance in the shear direction (e.g. x direction
for xy deformation) from the unstrained orientation.

The tilt factor T as a function of time will change as

    T(t) = T0 exp(trate\*dt)

where T0 is the initial tilt factor and dt is the elapsed time (in time
units). Thus if *trate* R is specified as ln(1.1) and time units are
picoseconds, this means the shear strain or tilt factor will increase by
10% every picosecond. I.e. if the xy shear strain was initially 0.1,
then strain after 1 ps = 0.11, strain after 2 ps = 0.121, etc. R = ln(2)
or ln(3) means the tilt factor will double or triple every picosecond. R
= ln(0.99) means the tilt factor will shrink by 1% every picosecond.
Note that the change is continuous, so running with R = ln(2) for 10
picoseconds does not change the tilt factor by a factor of 10, but by a
factor of 1024 since it doubles every picosecond. Note that the initial
tilt factor must be non-zero to use the *trate* option.

Note that shear strain is defined as the tilt factor divided by the
perpendicular box length. The *erate* and *trate* styles control the
tilt factor, but assume the perpendicular box length remains constant.
If this is not the case (e.g. it changes due to another fix deform
parameter), then this effect on the shear strain is ignored.

The *wiggle* style oscillates the specified tilt factor sinusoidally
with the specified amplitude and period. I.e. the tilt factor T as a
function of time is given by

    T(t) = T0 + A sin(2\*pi t/Tp)

where T0 is its initial value. If the amplitude A is a positive number
the tilt factor initially becomes more positive, then more negative,
etc. If A is negative then the tilt factor initially becomes more
negative, then more positive, etc. The amplitude can be in lattice or
box distance units. See the discussion of the units keyword below.

The *variable* style changes the specified tilt factor by evaluating a
variable, which presumably is a function of time. The variable with
*name1* must be an [equal-style variable](variable) and should calculate
a change in tilt in units of distance. Note that this distance is in box
units, not lattice units; see the discussion of the *units* keyword
below. The formula associated with variable *name1* can reference the
current timestep. Note that it should return the \"change\" in tilt
factor, not the absolute tilt factor. This means it should evaluate to
0.0 when invoked on the initial timestep of the run following the
definition of fix deform.

The variable *name2* must also be an [equal-style variable](variable)
and should calculate the rate of tilt change, in units of distance/time,
i.e. the time-derivative of the *name1* variable. This quantity is used
internally by LAMMPS to reset atom velocities when they cross periodic
boundaries. It is computed internally for the other styles, but you must
provide it when using an arbitrary variable.

Here is an example of using the *variable* style to perform the same box
deformation as the *wiggle* style formula listed above, where we assume
that the current timestep = 0.

``` LAMMPS
variable A equal 5.0
variable Tp equal 10.0
variable displace equal "v_A * sin(2*PI * step*dt/v_Tp)"
variable rate equal "2*PI*v_A/v_Tp * cos(2*PI * step*dt/v_Tp)"
fix 2 all deform 1 xy variable v_displace v_rate remap v
```

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

All of the tilt styles change the xy, xz, yz tilt factors during a
simulation. In LAMMPS, tilt factors (xy,xz,yz) for triclinic boxes are
normally bounded by half the distance of the parallel box length. See
the discussion of the *flip* keyword below, to allow this bound to be
exceeded, if desired.

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 all
equivalent.

To obey this constraint and allow for large shear deformations to be
applied via the *xy*, *xz*, or *yz* parameters, the following algorithm
is used. If *prd* is the associated parallel box length (10 in the
example above), then if the tilt factor exceeds the accepted range of -5
to 5 during the simulation, then the box is flipped to the other limit
(an equivalent box) and the simulation continues. Thus for this example,
if the initial xy tilt factor was 0.0 and \"xy final 100.0\" was
specified, then during the simulation the xy tilt factor would increase
from 0.0 to 5.0, the box would be flipped so that the tilt factor
becomes -5.0, the tilt factor would increase from -5.0 to 5.0, the box
would be flipped again, etc. The flip occurs 10 times and the final tilt
factor at the end of the simulation would be 0.0. During each flip
event, atoms are remapped into the new box in the appropriate manner.

The one exception to this rule is if the first 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.

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

Each time the box size or shape is changed, the *remap* keyword
determines whether atom positions are remapped to the new box. If
*remap* is set to *x* (the default), atoms in the fix group are
remapped; otherwise they are not. Note that their velocities are not
changed, just their positions are altered. If *remap* is set to *v*,
then any atom in the fix group that crosses a periodic boundary will
have a delta added to its velocity equal to the difference in velocities
between the lo and hi boundaries. Note that this velocity difference can
include tilt components, e.g. a delta in the x velocity when an atom
crosses the y periodic boundary. If *remap* is set to *none*, then
neither of these remappings take place.

Conceptually, setting *remap* to *x* forces the atoms to deform via an
affine transformation that exactly matches the box deformation. This
setting is typically appropriate for solids. Note that though the atoms
are effectively \"moving\" with the box over time, it is not due to
their having a velocity that tracks the box change, but only due to the
remapping. By contrast, setting *remap* to *v* is typically appropriate
for fluids, where you want the atoms to respond to the change in box
size/shape on their own and acquire a velocity that matches the box
change, so that their motion will naturally track the box without
explicit remapping of their coordinates.

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

When non-equilibrium MD (NEMD) simulations are performed using this fix,
the option \"remap v\" should normally be used. This is because [fix
nvt/sllod](fix_nvt_sllod) adjusts the atom positions and velocities to
induce a velocity profile that matches the changing box size/shape. Thus
atom coordinates should NOT be remapped by fix deform, but velocities
SHOULD be when atoms cross periodic boundaries, since that is consistent
with maintaining the velocity profile already created by fix nvt/sllod.
LAMMPS will warn you if the *remap* setting is not consistent with fix
nvt/sllod.
::::

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

For non-equilibrium MD (NEMD) simulations using \"remap v\" it is
usually desirable that the fluid (or flowing material, e.g. granular
particles) stream with a velocity profile consistent with the deforming
box. As mentioned above, using a thermostat such as [fix
nvt/sllod](fix_nvt_sllod) or [fix lavgevin](fix_langevin) (with a bias
provided by [compute temp/deform](compute_temp_deform)), will typically
accomplish that. If you do not use a thermostat, then there is no
driving force pushing the atoms to flow in a manner consistent with the
deforming box. E.g. for a shearing system the box deformation velocity
may vary from 0 at the bottom to 10 at the top of the box. But the
stream velocity profile of the atoms may vary from -5 at the bottom to
+5 at the top. You can monitor these effects using the [fix
ave/chunk](fix_ave_chunk), [compute temp/deform](compute_temp_deform),
and [compute temp/profile](compute_temp_profile) commands. One way to
induce atoms to stream consistent with the box deformation is to give
them an initial velocity profile, via the [velocity ramp](velocity)
command, that matches the box deformation rate. This also typically
helps the system come to equilibrium more quickly, even if a thermostat
is used.
::::

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

If a [fix rigid](fix_rigid) is defined for rigid bodies, and *remap* is
set to *x*, then the center-of-mass coordinates of rigid bodies will be
remapped to the changing simulation box. This will be done regardless of
whether atoms in the rigid bodies are in the fix deform group or not.
The velocity of the centers of mass are not remapped even if *remap* is
set to *v*, since [fix nvt/sllod](fix_nvt_sllod) does not currently do
anything special for rigid particles. If you wish to perform a NEMD
simulation of rigid particles, you can either thermostat them
independently or include a background fluid and thermostat the fluid via
[fix nvt/sllod](fix_nvt_sllod).
::::

The *flip* keyword allows the tilt factors for a triclinic box to exceed
half the distance of the parallel box length, as discussed above. If the
*flip* value is set to *yes*, the bound is enforced by flipping the box
when it is exceeded. If the *flip* value is set to *no*, the tilt will
continue to change without flipping. Note that if you apply large
deformations, this means the box shape can tilt dramatically LAMMPS will
run less efficiently, due to the large volume of communication needed to
acquire ghost atoms around a processor\'s irregular-shaped subdomain.
For extreme values of tilt, LAMMPS may also lose atoms and generate an
error.

The *units* keyword determines the meaning of the distance units used to
define various arguments. A *box* value selects standard distance units
as defined by the [units](units) command, e.g. Angstroms for units =
real or metal. A *lattice* value means the distance units are in lattice
spacings. The [lattice](lattice) command must have been previously used
to define the lattice spacing. Note that the units choice also affects
the *vel* style parameters since it is defined in terms of
distance/time. Also note that the units keyword does not affect the
*variable* style. You should use the *xlat*, *ylat*, *zlat* keywords of
the [thermo_style](thermo_style) command if you want to include lattice
spacings in a variable formula.

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

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 will restore the initial box settings from [binary restart
files](restart), which allows the fix to be properly continue
deformation, when using the start/stop options of the [run](run)
command. 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).

This fix can perform deformation over multiple runs, using the *start*
and *stop* keywords of the [run](run) command. See the [run](run)
command for details of how to do this.

This fix is not invoked during [energy minimization](minimize).

## Restrictions

You cannot apply x, y, or z deformations to a dimension that is
shrink-wrapped via the [boundary](boundary) command.

You cannot apply xy, yz, or xz deformations to a second dimension (y in
xy) that is shrink-wrapped via the [boundary](boundary) command.

## Related commands

[change_box](change_box)

## Default

The option defaults are remap = x, flip = yes, and units = lattice.