pair_lj.html
No OneTemporary
Actions

Subscribers

None

File Metadata

Created: Tue, Oct 1, 02:29

pair_lj.html
View Options

	<HTML>
	<CENTER><A HREF = "http://lammps.sandia.gov">LAMMPS WWW Site</A> - <A HREF = "Manual.html">LAMMPS Documentation</A> - <A HREF = "Section_commands.html#comm">LAMMPS Commands</A>
	</CENTER>






	<HR>

	<H3>pair_style lj/cut command
	</H3>
	<H3>pair_style lj/cut/cuda command
	</H3>
	<H3>pair_style lj/cut/gpu command
	</H3>
	<H3>pair_style lj/cut/intel command
	</H3>
	<H3>pair_style lj/cut/kk command
	</H3>
	<H3>pair_style lj/cut/opt command
	</H3>
	<H3>pair_style lj/cut/omp command
	</H3>
	<H3>pair_style lj/cut/coul/cut command
	</H3>
	<H3>pair_style lj/cut/coul/cut/cuda command
	</H3>
	<H3>pair_style lj/cut/coul/cut/gpu command
	</H3>
	<H3>pair_style lj/cut/coul/cut/omp command
	</H3>
	<H3>pair_style lj/cut/coul/debye command
	</H3>
	<H3>pair_style lj/cut/coul/debye/cuda command
	</H3>
	<H3>pair_style lj/cut/coul/debye/gpu command
	</H3>
	<H3>pair_style lj/cut/coul/debye/kk command
	</H3>
	<H3>pair_style lj/cut/coul/debye/omp command
	</H3>
	<H3>pair_style lj/cut/coul/dsf command
	</H3>
	<H3>pair_style lj/cut/coul/dsf/gpu command
	</H3>
	<H3>pair_style lj/cut/coul/dsf/kk command
	</H3>
	<H3>pair_style lj/cut/coul/dsf/omp command
	</H3>
	<H3>pair_style lj/cut/coul/long command
	</H3>
	<H3>pair_style lj/cut/coul/long/cs command
	</H3>
	<H3>pair_style lj/cut/coul/long/cuda command
	</H3>
	<H3>pair_style lj/cut/coul/long/gpu command
	</H3>
	<H3>pair_style lj/cut/coul/long/intel command
	</H3>
	<H3>pair_style lj/cut/coul/long/opt command
	</H3>
	<H3>pair_style lj/cut/coul/long/omp command
	</H3>
	<H3>pair_style lj/cut/coul/msm command
	</H3>
	<H3>pair_style lj/cut/coul/msm/gpu command
	</H3>
	<H3>pair_style lj/cut/coul/msm/omp command
	</H3>
	<H3>pair_style lj/cut/tip4p/cut command
	</H3>
	<H3>pair_style lj/cut/tip4p/cut/omp command
	</H3>
	<H3>pair_style lj/cut/tip4p/long command
	</H3>
	<H3>pair_style lj/cut/tip4p/long/omp command
	</H3>
	<H3>pair_style lj/cut/tip4p/long/opt command
	</H3>
	<P><B>Syntax:</B>
	</P>
	<PRE>pair_style style args
	</PRE>
	<UL><LI>style = <I>lj/cut</I> or <I>lj/cut/coul/cut</I> or <I>lj/cut/coul/debye</I> or <I>lj/cut/coul/dsf</I> or <I>lj/cut/coul/long</I> or <I>lj/cut/coul/long/cs</I> or <I>lj/cut/coul/msm</I> or <I>lj/cut/tip4p/long</I>
	<LI>args = list of arguments for a particular style
	</UL>
	<PRE> <I>lj/cut</I> args = cutoff
	cutoff = global cutoff for Lennard Jones interactions (distance units)
	<I>lj/cut/coul/cut</I> args = cutoff (cutoff2)
	cutoff = global cutoff for LJ (and Coulombic if only 1 arg) (distance units)
	cutoff2 = global cutoff for Coulombic (optional) (distance units)
	<I>lj/cut/coul/debye</I> args = kappa cutoff (cutoff2)
	kappa = inverse of the Debye length (inverse distance units)
	cutoff = global cutoff for LJ (and Coulombic if only 1 arg) (distance units)
	cutoff2 = global cutoff for Coulombic (optional) (distance units)
	<I>lj/cut/coul/dsf</I> args = alpha cutoff (cutoff2)
	alpha = damping parameter (inverse distance units)
	cutoff = global cutoff for LJ (and Coulombic if only 1 arg) (distance units)
	cutoff2 = global cutoff for Coulombic (distance units)
	<I>lj/cut/coul/long</I> args = cutoff (cutoff2)
	cutoff = global cutoff for LJ (and Coulombic if only 1 arg) (distance units)
	cutoff2 = global cutoff for Coulombic (optional) (distance units)
	<I>lj/cut/coul/msm</I> args = cutoff (cutoff2)
	cutoff = global cutoff for LJ (and Coulombic if only 1 arg) (distance units)
	cutoff2 = global cutoff for Coulombic (optional) (distance units)
	<I>lj/cut/tip4p/cut</I> args = otype htype btype atype qdist cutoff (cutoff2)
	otype,htype = atom types for TIP4P O and H
	btype,atype = bond and angle types for TIP4P waters
	qdist = distance from O atom to massless charge (distance units)
	cutoff = global cutoff for LJ (and Coulombic if only 1 arg) (distance units)
	cutoff2 = global cutoff for Coulombic (optional) (distance units)
	<I>lj/cut/tip4p/long</I> args = otype htype btype atype qdist cutoff (cutoff2)
	otype,htype = atom types for TIP4P O and H
	btype,atype = bond and angle types for TIP4P waters
	qdist = distance from O atom to massless charge (distance units)
	cutoff = global cutoff for LJ (and Coulombic if only 1 arg) (distance units)
	cutoff2 = global cutoff for Coulombic (optional) (distance units)
	</PRE>
	<P><B>Examples:</B>
	</P>
	<PRE>pair_style lj/cut 2.5
	pair_coeff * * 1 1
	pair_coeff 1 1 1 1.1 2.8
	</PRE>
	<PRE>pair_style lj/cut/coul/cut 10.0
	pair_style lj/cut/coul/cut 10.0 8.0
	pair_coeff * * 100.0 3.0
	pair_coeff 1 1 100.0 3.5 9.0
	pair_coeff 1 1 100.0 3.5 9.0 9.0
	</PRE>
	<PRE>pair_style lj/cut/coul/debye 1.5 3.0
	pair_style lj/cut/coul/debye 1.5 2.5 5.0
	pair_coeff * * 1.0 1.0
	pair_coeff 1 1 1.0 1.5 2.5
	pair_coeff 1 1 1.0 1.5 2.5 5.0
	</PRE>
	<PRE>pair_style lj/cut/coul/dsf 0.05 2.5 10.0
	pair_coeff * * 1.0 1.0
	pair_coeff 1 1 1.0 1.0 2.5
	</PRE>
	<PRE>pair_style lj/cut/coul/long 10.0
	pair_style lj/cut/coul/long/cs 10.0
	pair_style lj/cut/coul/long 10.0 8.0
	pair_style lj/cut/coul/long/cs 10.0 8.0
	pair_coeff * * 100.0 3.0
	pair_coeff 1 1 100.0 3.5 9.0
	</PRE>
	<PRE>pair_style lj/cut/coul/msm 10.0
	pair_style lj/cut/coul/msm 10.0 8.0
	pair_coeff * * 100.0 3.0
	pair_coeff 1 1 100.0 3.5 9.0
	</PRE>
	<PRE>pair_style lj/cut/tip4p/cut 1 2 7 8 0.15 12.0
	pair_style lj/cut/tip4p/cut 1 2 7 8 0.15 12.0 10.0
	pair_coeff * * 100.0 3.0
	pair_coeff 1 1 100.0 3.5 9.0
	</PRE>
	<PRE>pair_style lj/cut/tip4p/long 1 2 7 8 0.15 12.0
	pair_style lj/cut/tip4p/long 1 2 7 8 0.15 12.0 10.0
	pair_coeff * * 100.0 3.0
	pair_coeff 1 1 100.0 3.5 9.0
	</PRE>
	<P><B>Description:</B>
	</P>
	<P>The <I>lj/cut</I> styles compute the standard 12/6 Lennard-Jones potential,
	given by
	</P>
	<CENTER><IMG SRC = "Eqs/pair_lj.jpg">
	</CENTER>
	<P>Rc is the cutoff.
	</P>
	<P>Style <I>lj/cut/coul/cut</I> adds a Coulombic pairwise interaction given by
	</P>
	<CENTER><IMG SRC = "Eqs/pair_coulomb.jpg">
	</CENTER>
	<P>where C is an energy-conversion constant, Qi and Qj are the charges on
	the 2 atoms, and epsilon is the dielectric constant which can be set
	by the <A HREF = "dielectric.html">dielectric</A> command. If one cutoff is
	specified in the pair_style command, it is used for both the LJ and
	Coulombic terms. If two cutoffs are specified, they are used as
	cutoffs for the LJ and Coulombic terms respectively.
	</P>
	<P>Style <I>lj/cut/coul/debye</I> adds an additional exp() damping factor
	to the Coulombic term, given by
	</P>
	<CENTER><IMG SRC = "Eqs/pair_debye.jpg">
	</CENTER>
	<P>where kappa is the inverse of the Debye length. This potential is
	another way to mimic the screening effect of a polar solvent.
	</P>
	<P>Style <I>lj/cut/coul/dsf</I> computes the Coulombic term via the damped
	shifted force model described in <A HREF = "#Fennell">Fennell</A>, given by:
	</P>
	<CENTER><IMG SRC = "Eqs/pair_coul_dsf.jpg">
	</CENTER>
	<P>where <I>alpha</I> is the damping parameter and erfc() is the complementary
	error-function. This potential is essentially a short-range,
	spherically-truncated, charge-neutralized, shifted, pairwise <I>1/r</I>
	summation. The potential is based on Wolf summation, proposed as an
	alternative to Ewald summation for condensed phase systems where
	charge screening causes electrostatic interactions to become
	effectively short-ranged. In order for the electrostatic sum to be
	absolutely convergent, charge neutralization within the cutoff radius
	is enforced by shifting the potential through placement of image
	charges on the cutoff sphere. Convergence can often be improved by
	setting <I>alpha</I> to a small non-zero value.
	</P>
	<P>Styles <I>lj/cut/coul/long</I> and <I>lj/cut/coul/msm</I> compute the same
	Coulombic interactions as style <I>lj/cut/coul/cut</I> except that an
	additional damping factor is applied to the Coulombic term so it can
	be used in conjunction with the <A HREF = "kspace_style.html">kspace_style</A>
	command and its <I>ewald</I> or <I>pppm</I> option. The Coulombic cutoff
	specified for this style means that pairwise interactions within this
	distance are computed directly; interactions outside that distance are
	computed in reciprocal space.
	</P>
	<P>Style <I>lj/cut/coul/long/cs</I> is identical to <I>lj/cut/coul/long</I> except
	that a term is added for the <A HREF = "Section_howto.html#howto_25">core/shell
	model</A> to allow charges on core and shell
	particles to be separated by r = 0.0.
	</P>
	<P>Styles <I>lj/cut/tip4p/cut</I> and <I>lj/cut/tip4p/long</I> implement the TIP4P
	water model of <A HREF = "#Jorgensen">(Jorgensen)</A>, which introduces a massless
	site located a short distance away from the oxygen atom along the
	bisector of the HOH angle. The atomic types of the oxygen and
	hydrogen atoms, the bond and angle types for OH and HOH interactions,
	and the distance to the massless charge site are specified as
	pair_style arguments. Style <I>lj/cut/tip4p/cut</I> uses a cutoff for
	Coulomb interactions; style <I>lj/cut/tip4p/long</I> is for use with a
	long-range Coulombic solver (Ewald or PPPM).
	</P>
	<P>IMPORTANT NOTE: For each TIP4P water molecule in your system, the atom
	IDs for the O and 2 H atoms must be consecutive, with the O atom
	first. This is to enable LAMMPS to "find" the 2 H atoms associated
	with each O atom. For example, if the atom ID of an O atom in a TIP4P
	water molecule is 500, then its 2 H atoms must have IDs 501 and 502.
	</P>
	<P>See the <A HREF = "Section_howto.html#howto_8">howto section</A> for more
	information on how to use the TIP4P pair styles and lists of
	parameters to set. Note that the neighobr list cutoff for Coulomb
	interactions is effectively extended by a distance 2*qdist when using
	the TIP4P pair style, to account for the offset distance of the
	fictitious charges on O atoms in water molecules. Thus it is
	typically best in an efficiency sense to use a LJ cutoff >= Coulomb
	cutoff + 2*qdist, to shrink the size of the neighbor list. This leads
	to slightly larger cost for the long-range calculation, so you can
	test the trade-off for your model.
	</P>
	<P>For all of the <I>lj/cut</I> pair styles, the following coefficients must
	be defined for each pair of atoms types via the
	<A HREF = "pair_coeff.html">pair_coeff</A> command as in the examples above, or in
	the data file or restart files read by the <A HREF = "read_data.html">read_data</A>
	or <A HREF = "read_restart.html">read_restart</A> commands, or by mixing as
	described below:
	</P>
	<UL><LI>epsilon (energy units)
	<LI>sigma (distance units)
	<LI>cutoff1 (distance units)
	<LI>cutoff2 (distance units)
	</UL>
	<P>Note that sigma is defined in the LJ formula as the zero-crossing
	distance for the potential, not as the energy minimum at 2^(1/6)
	sigma.
	</P>
	<P>The latter 2 coefficients are optional. If not specified, the global
	LJ and Coulombic cutoffs specified in the pair_style command are used.
	If only one cutoff is specified, it is used as the cutoff for both LJ
	and Coulombic interactions for this type pair. If both coefficients
	are specified, they are used as the LJ and Coulombic cutoffs for this
	type pair. You cannot specify 2 cutoffs for style <I>lj/cut</I>, since it
	has no Coulombic terms.
	</P>
	<P>For <I>lj/cut/coul/long</I> and <I>lj/cut/coul/msm</I> and <I>lj/cut/tip4p/cut</I>
	and <I>lj/cut/tip4p/long</I> only the LJ cutoff can be specified since a
	Coulombic cutoff cannot be specified for an individual I,J type pair.
	All type pairs use the same global Coulombic cutoff specified in the
	pair_style command.
	</P>
	<HR>

	<P>Styles with a <I>cuda</I>, <I>gpu</I>, <I>intel</I>, <I>kk</I>, <I>omp</I>, or <I>opt</I> 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 in <A HREF = "Section_accelerate.html">Section_accelerate</A>
	of the manual. The accelerated styles take the same arguments and
	should produce the same results, except for round-off and precision
	issues.
	</P>
	<P>These accelerated styles are part of the USER-CUDA, GPU, USER-INTEL,
	KOKKOS, USER-OMP and OPT packages, respectively. They are only
	enabled if LAMMPS was built with those packages. See the <A HREF = "Section_start.html#start_3">Making
	LAMMPS</A> section for more info.
	</P>
	<P>You can specify the accelerated styles explicitly in your input script
	by including their suffix, or you can use the <A HREF = "Section_start.html#start_7">-suffix command-line
	switch</A> when you invoke LAMMPS, or you can
	use the <A HREF = "suffix.html">suffix</A> command in your input script.
	</P>
	<P>See <A HREF = "Section_accelerate.html">Section_accelerate</A> of the manual for
	more instructions on how to use the accelerated styles effectively.
	</P>
	<HR>

	<P><B>Mixing, shift, table, tail correction, restart, rRESPA info</B>:
	</P>
	<P>For atom type pairs I,J and I != J, the epsilon and sigma coefficients
	and cutoff distance for all of the lj/cut pair styles can be mixed.
	The default mix value is <I>geometric</I>. See the "pair_modify" command
	for details.
	</P>
	<P>All of the <I>lj/cut</I> pair styles support the
	<A HREF = "pair_modify.html">pair_modify</A> shift option for the energy of the
	Lennard-Jones portion of the pair interaction.
	</P>
	<P>The <I>lj/cut/coul/long</I> and <I>lj/cut/tip4p/long</I> pair styles support the
	<A HREF = "pair_modify.html">pair_modify</A> table option since they can tabulate
	the short-range portion of the long-range Coulombic interaction.
	</P>
	<P>All of the <I>lj/cut</I> pair styles support the
	<A HREF = "pair_modify.html">pair_modify</A> tail option for adding a long-range
	tail correction to the energy and pressure for the Lennard-Jones
	portion of the pair interaction.
	</P>
	<P>All of the <I>lj/cut</I> pair styles write their information to <A HREF = "restart.html">binary
	restart files</A>, so pair_style and pair_coeff commands do
	not need to be specified in an input script that reads a restart file.
	</P>
	<P>The <I>lj/cut</I> and <I>lj/cut/coul/long</I> pair styles support the use of the
	<I>inner</I>, <I>middle</I>, and <I>outer</I> keywords of the <A HREF = "run_style.html">run_style
	respa</A> command, meaning the pairwise forces can be
	partitioned by distance at different levels of the rRESPA hierarchy.
	The other styles only support the <I>pair</I> keyword of run_style respa.
	See the <A HREF = "run_style.html">run_style</A> command for details.
	</P>
	<HR>

	<P><B>Restrictions:</B>
	</P>
	<P>The <I>lj/cut/coul/long</I> and <I>lj/cut/tip4p/long</I> styles are part of the
	KSPACE package. The <I>lj/cut/tip4p/cut</I> style is part of the MOLECULE
	package. These styles are only enabled if LAMMPS was built with those
	packages. See the <A HREF = "Section_start.html#start_3">Making LAMMPS</A> section
	for more info. Note that the KSPACE and MOLECULE packages are
	installed by default.
	</P>
	<P><B>Related commands:</B>
	</P>
	<P><A HREF = "pair_coeff.html">pair_coeff</A>
	</P>
	<P><B>Default:</B> none
	</P>
	<HR>

	<A NAME = "Jorgensen"></A>

	<P><B>(Jorgensen)</B> Jorgensen, Chandrasekhar, Madura, Impey, Klein, J Chem
	Phys, 79, 926 (1983).
	</P>
	<A NAME = "Fennell"></A>

	<P><B>(Fennell)</B> C. J. Fennell, J. D. Gezelter, J Chem Phys, 124,
	234104 (2006).
	</P>
	</HTML>

pair_lj.htmlNo OneTemporaryActions

File Metadata

pair_lj.htmlView Options

Event Timeline

pair_lj.html
No OneTemporary
Actions

pair_lj.html
View Options