10. System manipulation¶
10.1. Changing the box volume¶
This is implemented in
espressomd.system.System.change_volume_and_rescale_particles()
with the parameters d_new
for the new length and dir
for the
coordinates to work on and "xyz"
for isotropic.
Changes the volume of either a cubic simulation box to the new volume or its given x-/y-/z-/xyz-extension to the new box-length, and isotropically adjusts the particles coordinates as well. The function returns the new volume of the deformed simulation box.
10.2. Stopping particles¶
To stop particles you can use the functionality implemented in the
espressomd.galilei
module. The corresponding class
espressomd.galilei.GalileiTransform
which is wrapped inside
the espressomd.system.System
instance as
espressomd.system.System.galilei
has two functions:
espressomd.galilei.GalileiTransform.kill_particle_motion()
:- halts all particles in the current simulation, setting their
velocities to zero, as well as their angular momentum if the
feature
ROTATION
has been compiled in.
espressomd.galilei.GalileiTransform.kill_particle_forces()
:- sets all forces on the particles to zero, as well as all torques if
the feature
ROTATION
has been compiled in.
10.3. Fixing the center of mass¶
This interaction type applies a constraint on particles of the specified types such that during the integration the center of mass of these particles is fixed. This is accomplished as follows: The sum of all the forces acting on particles of type are calculated. These include all the forces due to other interaction types and also the thermostat. Next a force equal in magnitude, but in the opposite direction is applied to all the particles. This force is divided on the particles of type relative to their respective mass. Under periodic boundary conditions, this fixes the itinerant center of mass, that is, the one obtained from the unfolded coordinates.
Center of mass fixing can be activated via espressomd.system.System
:
system.comfixed.types = list_of_types_to_fix
10.4. Capping the force during warmup¶
Non-bonded interactions are often used to model the hard core repulsion between particles. Most of the potentials in the section are therefore singular at zero distance, and forces usually become very large for distances below the particle size. This is not a problem during the simulation, as particles will simply avoid overlapping. However, creating an initial dense random configuration without overlap is often difficult. By artificially capping the forces, it is possible to simulate a system with overlaps. By gradually raising the cap value, possible overlaps become unfavorable, and the system equilibrates to a overlap free configuration.
Force capping can be activated via espressomd.system.System
:
system.force_cap = F_max
This command will limit the magnitude of the force to \(r F_\mathrm{max}\). Energies are not affected by the capping, so the energy can be used to identify the remaining overlap. The force capping is switched off by setting \(F_\mathrm{max}=0\).
10.5. Galilei Transform and Particle Velocity Manipulation¶
The following class espressomd.galilei.GalileiTransform
may be useful
in affecting the velocity of the system.
system = espressomd.System()
gt = system.galilei
- Particle motion and rotation
gt.kill_particle_motion()
This command halts all particles in the current simulation, setting
their velocities to zero, as well as their angular momentum if the
option rotation
is specified and the feature ROTATION
has been
compiled in.
Forces and torques acting on the particles
gt.kill_particle_forces()
This command sets all forces on the particles to zero, as well as all torques if the option
torque
is specified and the featureROTATION
has been compiled in.The center of mass of the system
gt.system_CMS()
Returns the center of mass of the whole system. It currently does not factor in the density fluctuations of the lattice Boltzmann fluid.
The center-of-mass velocity
gt.system_CMS_velocity()
Returns the velocity of the center of mass of the whole system.
The Galilei transform
gt.galilei_transform()
Subtracts the velocity of the center of mass of the whole system from every particle’s velocity, thereby performing a Galilei transform into the reference frame of the center of mass of the system. This transformation is useful for example in combination with the DPD thermostat, since there, a drift in the velocity of the whole system leads to an offset in the reported temperature.