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rLAMMPS lammps
pair_resquared.html
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<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 resquared command
</H3>
<H3>
pair_style resquared/gpu command
</H3>
<H3>
pair_style resquared/omp command
</H3>
<P><B>
Syntax:
</B>
</P>
<PRE>
pair_style resquared cutoff
</PRE>
<UL><LI>
cutoff = global cutoff for interactions (distance units)
</UL>
<P><B>
Examples:
</B>
</P>
<PRE>
pair_style resquared 10.0
pair_coeff * * 1.0 1.0 1.7 3.4 3.4 1.0 1.0 1.0
</PRE>
<P><B>
Description:
</B>
</P>
<P>
Style
<I>
resquared
</I>
computes the RE-squared anisotropic interaction
<A
HREF =
"#Everaers"
>
(Everaers)
</A>
,
<A
HREF =
"#Babadi"
>
(Babadi)
</A>
between pairs of
ellipsoidal and/or spherical Lennard-Jones particles. For ellipsoidal
interactions, the potential considers the ellipsoid as being comprised
of small spheres of size sigma. LJ particles are a single sphere of
size sigma. The distinction is made to allow the pair style to make
efficient calculations of ellipsoid/solvent interactions.
</P>
<P>
Details for the equations used are given in the references below and
in
<A
HREF =
"PDF/pair_resquared_extra.pdf"
>
this supplementary document
</A>
.
</P>
<P>
Use of this pair style requires the NVE, NVT, or NPT fixes with the
<I>
asphere
</I>
extension (e.g.
<A
HREF =
"fix_nve_asphere.html"
>
fix nve/asphere
</A>
) in
order to integrate particle rotation. Additionally,
<A
HREF =
"atom_style.html"
>
atom_style
ellipsoid
</A>
should be used since it defines the
rotational state and the size and shape of each ellipsoidal particle.
</P>
<P>
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:
</P>
<UL><LI>
A12 = Energy Prefactor/Hamaker constant (energy units)
<LI>
sigma = atomic interaction diameter (distance units)
<LI>
epsilon_i_a = relative well depth of type I for side-to-side interactions
<LI>
epsilon_i_b = relative well depth of type I for face-to-face interactions
<LI>
epsilon_i_c = relative well depth of type I for end-to-end interactions
<LI>
epsilon_j_a = relative well depth of type J for side-to-side interactions
<LI>
epsilon_j_b = relative well depth of type J for face-to-face interactions
<LI>
epsilon_j_c = relative well depth of type J for end-to-end interactions
<LI>
cutoff (distance units)
</UL>
<P>
The parameters used depend on the type of the interacting particles,
i.e. ellipsoids or LJ spheres. The type of a particle is determined
by the diameters specified for its 3 shape paramters. If all 3 shape
parameters = 0.0, then the particle is treated as an LJ sphere. The
epsilon_i_* or epsilon_j_* parameters are ignored for LJ spheres. If
the 3 shape paraemters are > 0.0, then the particle is treated as an
ellipsoid (even if the 3 parameters are equal to each other).
</P>
<P>
A12 specifies the energy prefactor which depends on the types of the
two interacting particles.
</P>
<P>
For ellipsoid/ellipsoid interactions, the interaction is computed by
the formulas in the supplementary docuement referenced above. A12 is
the Hamaker constant as described in
<A
HREF =
"#Everaers"
>
(Everaers)
</A>
. In LJ
units:
</P>
<CENTER><IMG
SRC =
"Eqs/pair_resquared.jpg"
>
</CENTER>
<P>
where rho gives the number density of the spherical particles
composing the ellipsoids and epsilon_LJ determines the interaction
strength of the spherical particles.
</P>
<P>
For ellipsoid/LJ sphere interactions, the interaction is also computed
by the formulas in the supplementary docuement referenced above. A12
has a modifed form (see
<A
HREF =
"PDF/pair_resquared_extra.pdf"
>
here
</A>
for
details):
</P>
<CENTER><IMG
SRC =
"Eqs/pair_resquared2.jpg"
>
</CENTER>
<P>
For ellipsoid/LJ sphere interactions, a correction to the distance-
of-closest approach equation has been implemented to reduce the error
from two particles of disparate sizes; see
<A
HREF =
"PDF/pair_resquared_extra.pdf"
>
this supplementary
document
</A>
.
</P>
<P>
For LJ sphere/LJ sphere interactions, the interaction is computed
using the standard Lennard-Jones formula, which is much cheaper to
compute than the ellipsoidal formulas. A12 is used as epsilon in the
standard LJ formula:
</P>
<CENTER><IMG
SRC =
"Eqs/pair_resquared3.jpg"
>
</CENTER>
<P>
and the specified
<I>
sigma
</I>
is used as the sigma in the standard LJ
formula.
</P>
<P>
When one of both of the interacting particles are ellipsoids, then
<I>
sigma
</I>
specifies the diameter of the continuous distribution of
constituent particles within each ellipsoid used to model the
RE-squared potential. Note that this is a different meaning for
<I>
sigma
</I>
than the
<A
HREF =
"pair_gayberne.html"
>
pair_style gayberne
</A>
potential
uses.
</P>
<P>
The epsilon_i and epsilon_j coefficients are defined for atom types,
not for pairs of atom types. Thus, in a series of pair_coeff
commands, they only need to be specified once for each atom type.
</P>
<P>
Specifically, if any of epsilon_i_a, epsilon_i_b, epsilon_i_c are
non-zero, the three values are assigned to atom type I. If all the
epsilon_i values are zero, they are ignored. If any of epsilon_j_a,
epsilon_j_b, epsilon_j_c are non-zero, the three values are assigned
to atom type J. If all three epsilon_i values are zero, they are
ignored. Thus the typical way to define the epsilon_i and epsilon_j
coefficients is to list their values in "pair_coeff I J" commands when
I = J, but set them to 0.0 when I != J. If you do list them when I !=
J, you should insure they are consistent with their values in other
pair_coeff commands.
</P>
<P>
Note that if this potential is being used as a sub-style of
<A
HREF =
"pair_hybrid.html"
>
pair_style hybrid
</A>
, and there is no "pair_coeff I I"
setting made for RE-squared for a particular type I (because I-I
interactions are computed by another hybrid pair potential), then you
still need to insure the epsilon a,b,c coefficients are assigned to
that type in a "pair_coeff I J" command.
</P>
<P>
For large uniform molecules it has been shown that the epsilon_*_*
energy parameters are approximately representable in terms of local
contact curvatures
<A
HREF =
"#Everaers"
>
(Everaers)
</A>
:
</P>
<CENTER><IMG
SRC =
"Eqs/pair_resquared4.jpg"
>
</CENTER>
<P>
where a, b, and c give the particle diameters.
</P>
<P>
The last coefficient is optional. If not specified, the global cutoff
specified in the pair_style command is used.
</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 can be mixed, but only for sphere pairs. The
default mix value is
<I>
geometric
</I>
. See the "pair_modify" command for
details. Other type pairs cannot be mixed, due to the different
meanings of the energy prefactors used to calculate the interactions
and the implicit dependence of the ellipsoid-sphere interaction on the
equation for the Hamaker constant presented here. Mixing of sigma and
epsilon followed by calculation of the energy prefactors using the
equations above is recommended.
</P>
<P>
This pair styles supports the
<A
HREF =
"pair_modify.html"
>
pair_modify
</A>
shift
option for the energy of the Lennard-Jones portion of the pair
interaction, but only for sphere-sphere interactions. There is no
shifting performed for ellipsoidal interactions due to the anisotropic
dependence of the interaction.
</P>
<P>
The
<A
HREF =
"pair_modify.html"
>
pair_modify
</A>
table option is not relevant
for this pair style.
</P>
<P>
This pair style does not support the
<A
HREF =
"pair_modify.html"
>
pair_modify
</A>
tail option for adding long-range tail corrections to energy and
pressure.
</P>
<P>
This pair style writes its 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>
This pair style can only be used via the
<I>
pair
</I>
keyword of the
<A
HREF =
"run_style.html"
>
run_style respa
</A>
command. It does not support the
<I>
inner
</I>
,
<I>
middle
</I>
,
<I>
outer
</I>
keywords of the
<A
HREF =
"run_style.html"
>
run_style
command
</A>
.
</P>
<HR>
<P><B>
Restrictions:
</B>
</P>
<P>
This style is part of the ASPHERE package. It is only enabled if
LAMMPS was built with that package. See the
<A
HREF =
"Section_start.html#start_3"
>
Making
LAMMPS
</A>
section for more info.
</P>
<P>
This pair style requires that atoms be ellipsoids as defined by the
<A
HREF =
"atom_style.html"
>
atom_style ellipsoid
</A>
command.
</P>
<P>
Particles acted on by the potential can be finite-size aspherical or
spherical particles, or point particles. Spherical particles have all
3 of their shape parameters equal to each other. Point particles have
all 3 of their shape parameters equal to 0.0.
</P>
<P>
The distance-of-closest-approach approximation used by LAMMPS becomes
less accurate when high-aspect ratio ellipsoids are used.
</P>
<P><B>
Related commands:
</B>
</P>
<P><A
HREF =
"pair_coeff.html"
>
pair_coeff
</A>
,
<A
HREF =
"fix_nve_asphere.html"
>
fix nve/asphere
</A>
,
<A
HREF =
"compute_temp_asphere.html"
>
compute temp/asphere
</A>
,
<A
HREF =
"pair_gayberne.html"
>
pair_style
gayberne
</A>
</P>
<P><B>
Default:
</B>
none
</P>
<HR>
<A
NAME =
"Everaers"
></A>
<P><B>
(Everaers)
</B>
Everaers and Ejtehadi, Phys Rev E, 67, 041710 (2003).
</P>
<A
NAME =
"Babadi"
></A>
<P><B>
(Berardi)
</B>
Babadi, Ejtehadi, Everaers, J Comp Phys, 219, 770-779 (2006).
</P>
</HTML>
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