Syntax:
fix ID group gravity magnitude style args
chute args = angle
angle = angle in +x away from -z or -y axis in 3d/2d (in degrees)
angle can be a variable (see below)
spherical args = phi theta
phi = azimuthal angle from +x axis (in degrees)
theta = angle from +z or +y axis in 3d/2d (in degrees)
phi or theta can be a variable (see below)
vector args = x y z
x y z = vector direction to apply the acceleration
x or y or z can be a variable (see below)
Examples:
fix 1 all gravity 1.0 chute 24.0 fix 1 all gravity v_increase chute 24.0 fix 1 all gravity 1.0 spherical 0.0 -180.0 fix 1 all gravity 10.0 spherical v_phi v_theta fix 1 all gravity 100.0 vector 1 1 0
Description:
Impose an additional acceleration on each particle in the group. This fix is typically used with granular systems to include a "gravity" term acting on the macroscopic particles. More generally, it can represent any kind of driving field, e.g. a pressure gradient inducing a Poiseuille flow in a fluid. Note that this fix operates differently than the fix addforce command. The addforce fix adds the same force to each atom, independent of its mass. This command imparts the same acceleration to each atom (force/mass).
The magnitude of the acceleration is specified in force/mass units. For granular systems (LJ units) this is typically 1.0. See the units command for details.
Style chute is typically used for simulations of chute flow where the specified angle is the chute angle, with flow occurring in the +x direction. For 3d systems, the tilt is away from the z axis; for 2d systems, the tilt is away from the y axis.
Style spherical allows an arbitrary 3d direction to be specified for the acceleration vector. Phi and theta are defined in the usual spherical coordinates. Thus for acceleration acting in the -z direction, theta would be 180.0 (or -180.0). Theta = 90.0 and phi = -90.0 would mean acceleration acts in the -y direction. For 2d systems, phi is ignored and theta is an angle in the xy plane where theta = 0.0 is the y-axis.
Style vector imposes an acceleration in the vector direction given by (x,y,z). Only the direction of the vector is important; it's length is ignored. For 2d systems, the z component is ignored.
Any of the quantities magnitude, angle, phi, theta, x, y, z which define the gravitational magnitude and direction, can be specified as an equal-style variable. If the value is a variable, it should be specified as v_name, where name is the variable name. In this case, the variable will be evaluated each timestep, and its value used to determine the quantity. You should insure that the variable calculates a result in the approriate units, e.g. force/mass or degrees.
Equal-style variables can specify formulas with various mathematical functions, and include thermo_style command keywords for the simulation box parameters and timestep and elapsed time. Thus it is easy to specify a time-dependent gravitational field.
Restart, fix_modify, output, run start/stop, minimize info:
No information about this fix is written to binary restart files.
The fix_modify energy option is supported by this fix to add the gravitational potential energy of the system to the system's potential energy as part of thermodynamic output.
This fix computes a global scalar which can be accessed by various output commands. This scalar is the gravitational potential energy of the particles in the defined field, namely mass * (g dot x) for each particles, where x and mass are the particles position and mass, and g is the gravitational field. The scalar value calculated by this fix is "extensive".
No parameter of this fix can be used with the start/stop keywords of the run command. This fix is not invoked during energy minimization.
Restrictions: none
Related commands:
atom_style sphere, fix addforce
Default: none