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	<div class="section" id="fix-wall-lj93-command">
	<span id="index-0"></span><h1>fix wall/lj93 command</h1>
	</div>
	<div class="section" id="fix-wall-lj126-command">
	<h1>fix wall/lj126 command</h1>
	</div>
	<div class="section" id="fix-wall-lj1043-command">
	<h1>fix wall/lj1043 command</h1>
	</div>
	<div class="section" id="fix-wall-colloid-command">
	<h1>fix wall/colloid command</h1>
	</div>
	<div class="section" id="fix-wall-harmonic-command">
	<h1>fix wall/harmonic command</h1>
	<div class="section" id="syntax">
	<h2>Syntax</h2>
	<div class="highlight-default"><div class="highlight"><pre><span></span><span class="n">fix</span> <span class="n">ID</span> <span class="n">group</span><span class="o">-</span><span class="n">ID</span> <span class="n">style</span> <span class="n">face</span> <span class="n">args</span> <span class="o">...</span> <span class="n">keyword</span> <span class="n">value</span> <span class="o">...</span>
	</pre></div>
	</div>
	<ul class="simple">
	<li>ID, group-ID are documented in <a class="reference internal" href="fix.html"><span class="doc">fix</span></a> command</li>
	<li>style = <em>wall/lj93</em> or <em>wall/lj126</em> or <em>wall/lj1043</em> or <em>wall/colloid</em> or <em>wall/harmonic</em></li>
	<li>one or more face/arg pairs may be appended</li>
	<li>face = <em>xlo</em> or <em>xhi</em> or <em>ylo</em> or <em>yhi</em> or <em>zlo</em> or <em>zhi</em></li>
	</ul>
	<pre class="literal-block">
	args = coord epsilon sigma cutoff
	coord = position of wall = EDGE or constant or variable
	EDGE = current lo or hi edge of simulation box
	constant = number like 0.0 or -30.0 (distance units)
	variable = <a class="reference internal" href="variable.html"><span class="doc">equal-style variable</span></a> like v_x or v_wiggle
	epsilon = strength factor for wall-particle interaction (energy or energy/distance^2 units)
	epsilon can be a variable (see below)
	sigma = size factor for wall-particle interaction (distance units)
	sigma can be a variable (see below)
	cutoff = distance from wall at which wall-particle interaction is cut off (distance units)
	</pre>
	<ul class="simple">
	<li>zero or more keyword/value pairs may be appended</li>
	<li>keyword = <em>units</em> or <em>fld</em></li>
	</ul>
	<pre class="literal-block">
	<em>units</em> value = <em>lattice</em> or <em>box</em>
	<em>lattice</em> = the wall position is defined in lattice units
	<em>box</em> = the wall position is defined in simulation box units
	<em>fld</em> value = <em>yes</em> or <em>no</em>
	<em>yes</em> = invoke the wall constraint to be compatible with implicit FLD
	<em>no</em> = invoke the wall constraint in the normal way
	<em>pbc</em> value = <em>yes</em> or <em>no</em>
	<em>yes</em> = allow periodic boundary in a wall dimension
	<em>no</em> = require non-perioidic boundaries in any wall dimension
	</pre>
	</div>
	<div class="section" id="examples">
	<h2>Examples</h2>
	<div class="highlight-default"><div class="highlight"><pre><span></span><span class="n">fix</span> <span class="n">wallhi</span> <span class="nb">all</span> <span class="n">wall</span><span class="o">/</span><span class="n">lj93</span> <span class="n">xlo</span> <span class="o">-</span><span class="mf">1.0</span> <span class="mf">1.0</span> <span class="mf">1.0</span> <span class="mf">2.5</span> <span class="n">units</span> <span class="n">box</span>
	<span class="n">fix</span> <span class="n">wallhi</span> <span class="nb">all</span> <span class="n">wall</span><span class="o">/</span><span class="n">lj93</span> <span class="n">xhi</span> <span class="n">EDGE</span> <span class="mf">1.0</span> <span class="mf">1.0</span> <span class="mf">2.5</span>
	<span class="n">fix</span> <span class="n">wallhi</span> <span class="nb">all</span> <span class="n">wall</span><span class="o">/</span><span class="n">lj126</span> <span class="n">v_wiggle</span> <span class="mf">23.2</span> <span class="mf">1.0</span> <span class="mf">1.0</span> <span class="mf">2.5</span>
	<span class="n">fix</span> <span class="n">zwalls</span> <span class="nb">all</span> <span class="n">wall</span><span class="o">/</span><span class="n">colloid</span> <span class="n">zlo</span> <span class="mf">0.0</span> <span class="mf">1.0</span> <span class="mf">1.0</span> <span class="mf">0.858</span> <span class="n">zhi</span> <span class="mf">40.0</span> <span class="mf">1.0</span> <span class="mf">1.0</span> <span class="mf">0.858</span>
	</pre></div>
	</div>
	</div>
	<div class="section" id="description">
	<h2>Description</h2>
	<p>Bound the simulation domain on one or more of its faces with a flat
	wall that interacts with the atoms in the group by generating a force
	on the atom in a direction perpendicular to the wall. The energy of
	wall-particle interactions depends on the style.</p>
	<p>For style <em>wall/lj93</em>, the energy E is given by the 9/3 potential:</p>
	<img alt="_images/fix_wall_lj93.jpg" class="align-center" src="_images/fix_wall_lj93.jpg" />
	<p>For style <em>wall/lj126</em>, the energy E is given by the 12/6 potential:</p>
	<img alt="_images/pair_lj.jpg" class="align-center" src="_images/pair_lj.jpg" />
	<p>For style <em>wall/lj1043</em>, the energy E is given by the 10/4/3 potential:</p>
	<img alt="_images/fix_wall_lj1043.jpg" class="align-center" src="_images/fix_wall_lj1043.jpg" />
	<p>For style <em>wall/colloid</em>, the energy E is given by an integrated form
	of the <a class="reference internal" href="pair_colloid.html"><span class="doc">pair_style colloid</span></a> potential:</p>
	<img alt="_images/fix_wall_colloid.jpg" class="align-center" src="_images/fix_wall_colloid.jpg" />
	<p>For style <em>wall/harmonic</em>, the energy E is given by a harmonic spring
	potential:</p>
	<img alt="_images/fix_wall_harmonic.jpg" class="align-center" src="_images/fix_wall_harmonic.jpg" />
	<p>In all cases, <em>r</em> is the distance from the particle to the wall at
	position <em>coord</em>, and Rc is the <em>cutoff</em> distance at which the
	particle and wall no longer interact. The energy of the wall
	potential is shifted so that the wall-particle interaction energy is
	0.0 at the cutoff distance.</p>
	<p>Up to 6 walls or faces can be specified in a single command: <em>xlo</em>,
	<em>xhi</em>, <em>ylo</em>, <em>yhi</em>, <em>zlo</em>, <em>zhi</em>. A <em>lo</em> face interacts with
	particles near the lower side of the simulation box in that dimension.
	A <em>hi</em> face interacts with particles near the upper side of the
	simulation box in that dimension.</p>
	<p>The position of each wall can be specified in one of 3 ways: as the
	EDGE of the simulation box, as a constant value, or as a variable. If
	EDGE is used, then the corresponding boundary of the current
	simulation box is used. If a numeric constant is specified then the
	wall is placed at that position in the appropriate dimension (x, y, or
	z). In both the EDGE and constant cases, the wall will never move.
	If the wall position is a variable, it should be specified as v_name,
	where name is an <a class="reference internal" href="variable.html"><span class="doc">equal-style variable</span></a> name. In this
	case the variable is evaluated each timestep and the result becomes
	the current position of the reflecting wall. Equal-style variables
	can specify formulas with various mathematical functions, and include
	<a class="reference internal" href="thermo_style.html"><span class="doc">thermo_style</span></a> command keywords for the simulation
	box parameters and timestep and elapsed time. Thus it is easy to
	specify a time-dependent wall position. See examples below.</p>
	<p>For the <em>wall/lj93</em> and <em>wall/lj126</em> and <em>wall/lj1043</em> styles,
	<em>epsilon</em> and <em>sigma</em> are the usual Lennard-Jones parameters, which
	determine the strength and size of the particle as it interacts with
	the wall. Epsilon has energy units. Note that this <em>epsilon</em> and
	<em>sigma</em> may be different than any <em>epsilon</em> or <em>sigma</em> values defined
	for a pair style that computes particle-particle interactions.</p>
	<p>The <em>wall/lj93</em> interaction is derived by integrating over a 3d
	half-lattice of Lennard-Jones 12/6 particles. The <em>wall/lj126</em>
	interaction is effectively a harder, more repulsive wall interaction.
	The <em>wall/lj1043</em> interaction is yet a different form of wall
	interaction, described in Magda et al in <a class="reference internal" href="#magda"><span class="std std-ref">(Magda)</span></a>.</p>
	<p>For the <em>wall/colloid</em> style, <em>R</em> is the radius of the colloid
	particle, <em>D</em> is the distance from the surface of the colloid particle
	to the wall (r-R), and <em>sigma</em> is the size of a constituent LJ
	particle inside the colloid particle and wall. Note that the cutoff
	distance Rc in this case is the distance from the colloid particle
	center to the wall. The prefactor <em>epsilon</em> can be thought of as an
	effective Hamaker constant with energy units for the strength of the
	colloid-wall interaction. More specifically, the <em>epsilon</em> pre-factor
	= 4 * pi^2 * rho_wall * rho_colloid * epsilon * sigma^6, where epsilon
	and sigma are the LJ parameters for the constituent LJ
	particles. Rho_wall and rho_colloid are the number density of the
	constituent particles, in the wall and colloid respectively, in units
	of 1/volume.</p>
	<p>The <em>wall/colloid</em> interaction is derived by integrating over
	constituent LJ particles of size <em>sigma</em> within the colloid particle
	and a 3d half-lattice of Lennard-Jones 12/6 particles of size <em>sigma</em>
	in the wall. As mentioned in the preceeding paragraph, the density of
	particles in the wall and colloid can be different, as specified by
	the <em>epsilon</em> pre-factor.</p>
	<p>For the <em>wall/harmonic</em> style, <em>epsilon</em> is effectively the spring
	constant K, and has units (energy/distance^2). The input parameter
	<em>sigma</em> is ignored. The minimum energy position of the harmonic
	spring is at the <em>cutoff</em>. This is a repulsive-only spring since the
	interaction is truncated at the <em>cutoff</em></p>
	<p>For any wall, the <em>epsilon</em> and/or <em>sigma</em> parameter can be specified
	as an <a class="reference internal" href="variable.html"><span class="doc">equal-style variable</span></a>, in which case it should be
	specified as v_name, where name is the variable name. As with a
	variable wall position, the variable is evaluated each timestep and
	the result becomes the current epsilon or sigma of the wall.
	Equal-style variables can specify formulas with various mathematical
	functions, and include <a class="reference internal" href="thermo_style.html"><span class="doc">thermo_style</span></a> command
	keywords for the simulation box parameters and timestep and elapsed
	time. Thus it is easy to specify a time-dependent wall interaction.</p>
	<div class="admonition note">
	<p class="first admonition-title">Note</p>
	<p class="last">For all of the styles, you must insure that r is always > 0 for
	all particles in the group, or LAMMPS will generate an error. This
	means you cannot start your simulation with particles at the wall
	position <em>coord</em> (r = 0) or with particles on the wrong side of the
	wall (r < 0). For the <em>wall/lj93</em> and <em>wall/lj126</em> styles, the energy
	of the wall/particle interaction (and hence the force on the particle)
	blows up as r -> 0. The <em>wall/colloid</em> style is even more
	restrictive, since the energy blows up as D = r-R -> 0. This means
	the finite-size particles of radius R must be a distance larger than R
	from the wall position <em>coord</em>. The <em>harmonic</em> style is a softer
	potential and does not blow up as r -> 0, but you must use a large
	enough <em>epsilon</em> that particles always reamin on the correct side of
	the wall (r > 0).</p>
	</div>
	<p>The <em>units</em> keyword determines the meaning of the distance units used
	to define a wall position, but only when a numeric constant or
	variable is used. It is not relevant when EDGE is used to specify a
	face position. In the variable case, the variable is assumed to
	produce a value compatible with the <em>units</em> setting you specify.</p>
	<p>A <em>box</em> value selects standard distance units as defined by the
	<a class="reference internal" href="units.html"><span class="doc">units</span></a> command, e.g. Angstroms for units = real or metal.
	A <em>lattice</em> value means the distance units are in lattice spacings.
	The <a class="reference internal" href="lattice.html"><span class="doc">lattice</span></a> command must have been previously used to
	define the lattice spacings.</p>
	<p>The <em>fld</em> keyword can be used with a <em>yes</em> setting to invoke the wall
	constraint before pairwise interactions are computed. This allows an
	implicit FLD model using <a class="reference internal" href="pair_lubricateU.html"><span class="doc">pair_style lubricateU</span></a>
	to include the wall force in its calculations. If the setting is
	<em>no</em>, wall forces are imposed after pairwise interactions, in the
	usual manner.</p>
	<p>The <em>pbc</em> keyword can be used with a <em>yes</em> setting to allow walls to
	be specified in a periodic dimension. See the
	<a class="reference internal" href="boundary.html"><span class="doc">boundary</span></a> command for options on simulation box
	boundaries. The default for <em>pbc</em> is <em>no</em>, which means the system
	must be non-periodic when using a wall. But you may wish to use a
	periodic box. E.g. to allow some particles to interact with the wall
	via the fix group-ID, and others to pass through it and wrap around a
	periodic box. In this case you should insure that the wall if
	sufficiently far enough away from the box boundary. If you do not,
	then particles may interact with both the wall and with periodic
	images on the other side of the box, which is probably not what you
	want.</p>
	<hr class="docutils" />
	<p>Here are examples of variable definitions that move the wall position
	in a time-dependent fashion using equal-style
	<a class="reference internal" href="variable.html"><span class="doc">variables</span></a>. The wall interaction parameters (epsilon,
	sigma) could be varied with additional variable definitions.</p>
	<div class="highlight-default"><div class="highlight"><pre><span></span><span class="n">variable</span> <span class="n">ramp</span> <span class="n">equal</span> <span class="n">ramp</span><span class="p">(</span><span class="mi">0</span><span class="p">,</span><span class="mi">10</span><span class="p">)</span>
	<span class="n">fix</span> <span class="mi">1</span> <span class="nb">all</span> <span class="n">wall</span> <span class="n">xlo</span> <span class="n">v_ramp</span> <span class="mf">1.0</span> <span class="mf">1.0</span> <span class="mf">2.5</span>
	</pre></div>
	</div>
	<div class="highlight-default"><div class="highlight"><pre><span></span><span class="n">variable</span> <span class="n">linear</span> <span class="n">equal</span> <span class="n">vdisplace</span><span class="p">(</span><span class="mi">0</span><span class="p">,</span><span class="mi">20</span><span class="p">)</span>
	<span class="n">fix</span> <span class="mi">1</span> <span class="nb">all</span> <span class="n">wall</span> <span class="n">xlo</span> <span class="n">v_linear</span> <span class="mf">1.0</span> <span class="mf">1.0</span> <span class="mf">2.5</span>
	</pre></div>
	</div>
	<div class="highlight-default"><div class="highlight"><pre><span></span><span class="n">variable</span> <span class="n">wiggle</span> <span class="n">equal</span> <span class="n">swiggle</span><span class="p">(</span><span class="mf">0.0</span><span class="p">,</span><span class="mf">5.0</span><span class="p">,</span><span class="mf">3.0</span><span class="p">)</span>
	<span class="n">fix</span> <span class="mi">1</span> <span class="nb">all</span> <span class="n">wall</span> <span class="n">xlo</span> <span class="n">v_wiggle</span> <span class="mf">1.0</span> <span class="mf">1.0</span> <span class="mf">2.5</span>
	</pre></div>
	</div>
	<div class="highlight-default"><div class="highlight"><pre><span></span><span class="n">variable</span> <span class="n">wiggle</span> <span class="n">equal</span> <span class="n">cwiggle</span><span class="p">(</span><span class="mf">0.0</span><span class="p">,</span><span class="mf">5.0</span><span class="p">,</span><span class="mf">3.0</span><span class="p">)</span>
	<span class="n">fix</span> <span class="mi">1</span> <span class="nb">all</span> <span class="n">wall</span> <span class="n">xlo</span> <span class="n">v_wiggle</span> <span class="mf">1.0</span> <span class="mf">1.0</span> <span class="mf">2.5</span>
	</pre></div>
	</div>
	<p>The ramp(lo,hi) function adjusts the wall position linearly from lo to
	hi over the course of a run. The vdisplace(c0,velocity) function does
	something similar using the equation position = c0 + velocity*delta,
	where delta is the elapsed time.</p>
	<p>The swiggle(c0,A,period) function causes the wall position to
	oscillate sinusoidally according to this equation, where omega = 2 PI
	/ period:</p>
	<div class="highlight-default"><div class="highlight"><pre><span></span><span class="n">position</span> <span class="o">=</span> <span class="n">c0</span> <span class="o">+</span> <span class="n">A</span> <span class="n">sin</span><span class="p">(</span><span class="n">omega</span><span class="o">*</span><span class="n">delta</span><span class="p">)</span>
	</pre></div>
	</div>
	<p>The cwiggle(c0,A,period) function causes the wall position to
	oscillate sinusoidally according to this equation, which will have an
	initial wall velocity of 0.0, and thus may impose a gentler
	perturbation on the particles:</p>
	<div class="highlight-default"><div class="highlight"><pre><span></span><span class="n">position</span> <span class="o">=</span> <span class="n">c0</span> <span class="o">+</span> <span class="n">A</span> <span class="p">(</span><span class="mi">1</span> <span class="o">-</span> <span class="n">cos</span><span class="p">(</span><span class="n">omega</span><span class="o">*</span><span class="n">delta</span><span class="p">))</span>
	</pre></div>
	</div>
	</div>
	<hr class="docutils" />
	<div class="section" id="restart-fix-modify-output-run-start-stop-minimize-info">
	<h2>Restart, fix_modify, output, run start/stop, minimize info</h2>
	<p>No information about this fix is written to <a class="reference internal" href="restart.html"><span class="doc">binary restart files</span></a>.</p>
	<p>The <a class="reference internal" href="fix_modify.html"><span class="doc">fix_modify</span></a> <em>energy</em> option is supported by this
	fix to add the energy of interaction between atoms and each wall to
	the system’s potential energy as part of <a class="reference internal" href="thermo_style.html"><span class="doc">thermodynamic output</span></a>.</p>
	<p>The <a class="reference internal" href="fix_modify.html"><span class="doc">fix_modify</span></a> <em>respa</em> option is supported by this
	fix. This allows to set at which level of the <a class="reference internal" href="run_style.html"><span class="doc">r-RESPA</span></a>
	integrator the fix is adding its forces. Default is the outermost level.</p>
	<p>This fix computes a global scalar energy and a global vector of
	forces, which can be accessed by various <a class="reference internal" href="Section_howto.html#howto-15"><span class="std std-ref">output commands</span></a>. Note that the scalar energy is
	the sum of interactions with all defined walls. If you want the
	energy on a per-wall basis, you need to use multiple fix wall
	commands. The length of the vector is equal to the number of walls
	defined by the fix. Each vector value is the normal force on a
	specific wall. Note that an outward force on a wall will be a
	negative value for <em>lo</em> walls and a positive value for <em>hi</em> walls.
	The scalar and vector values calculated by this fix are “extensive”.</p>
	<p>No parameter of this fix can be used with the <em>start/stop</em> keywords of
	the <a class="reference internal" href="run.html"><span class="doc">run</span></a> command.</p>
	<p>The forces due to this fix are imposed during an energy minimization,
	invoked by the <a class="reference internal" href="minimize.html"><span class="doc">minimize</span></a> command.</p>
	<div class="admonition note">
	<p class="first admonition-title">Note</p>
	<p class="last">If you want the atom/wall interaction energy to be included in
	the total potential energy of the system (the quantity being
	minimized), you MUST enable the <a class="reference internal" href="fix_modify.html"><span class="doc">fix_modify</span></a> <em>energy</em>
	option for this fix.</p>
	</div>
	</div>
	<div class="section" id="restrictions">
	<h2>Restrictions</h2>
	<blockquote>
	<div>none</div></blockquote>
	</div>
	<div class="section" id="related-commands">
	<h2>Related commands</h2>
	<p><a class="reference internal" href="fix_wall_reflect.html"><span class="doc">fix wall/reflect</span></a>,
	<a class="reference internal" href="fix_wall_gran.html"><span class="doc">fix wall/gran</span></a>,
	<a class="reference internal" href="fix_wall_region.html"><span class="doc">fix wall/region</span></a></p>
	</div>
	<div class="section" id="default">
	<h2>Default</h2>
	<p>The option defaults units = lattice, fld = no, and pbc = no.</p>
	<hr class="docutils" />
	<p id="magda"><strong>(Magda)</strong> Magda, Tirrell, Davis, J Chem Phys, 83, 1888-1901 (1985);
	erratum in JCP 84, 2901 (1986).</p>
	</div>
	</div>


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