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UDF †

• UDF is a text file. One can browse and edit it using a text editor, but it.can be more easily handled with "Gourmet". See the manuals below for general information on UDF.
  • English: &ref(): File not found: "udf_spec_eng.pdf" at page "UdfFile";
  • Japanese: &ref(): File not found: "UDF_Spec_jpn.pdf" at page "UdfFile";

• In the case of UDF used for KAPSEL, one must first choose the type of problem you want to simulate by selecting "constitutive_eq" from list below.
  • Navier_Stokes: (sedimentation, diffusion, coagulation)
  • Shear_Navier_Stokes: (rheology, chain in shear flow)
  • Electrolyte: (electrophoresis)

List of variables in UDF for KAPSEL (input.udf) †

constitutive_eq: type: {Navier_Stokes, Shear_Navier_Stokes, Electrolyte}

Navier_Stokes

• DX: Girid width (this is the unit of length)
• RHO: Density of fluid
• ETA: Viscosity of fluid
• kBT: Temperature of dispersion
• alpha_v: Scaling factor for fluctuating force (translation)
• alpha_o: Scaling factor for fluctuating torque (rotation)

Shear_Navier_Stokes

• DX: Girid width (this is the unit of length)
• RHO: Density of fluid
• ETA: Viscosity of fluid
• kBT: Temperature of dispersion
• alpha_v: Scaling factor for fluctuating force (translation)
• alpha_o: Scaling factor for fluctuating torque (rotation)
• External_field: type: {DC, AC}: Steady shear (DC) or Oscillatory shear (AC)

DC

• shear_rate: Shear rate (DC)

AC

• shear_rate: Max shear rate (AC)

Electrolyte

• DX: Girid width (this is the unit of length)
• RHO: Density of fluid
• ETA: Viscosity of fluid
• kBT: Temperature of dispersion
• Dielectric_cst: Dielectric constant of fluid
• INIT_profile: Uniform: use uniform ionic densities as an initial state. Poisson_Boltzmann: use optimal ionic densities as an initial state by solving Poisson-Boltzman Eq. for a given initial particle configuration in advance to start simulation.
• Add_salt: type: salt: salt is added, saltfree: no salt is added

salt

• Valency_positive_ion: Valency of positive ions
• Valency_negative_ion: Valency of negative ions
• Onsager_coeff_positive_ion: Onsager transport coefficient of positive ions
• Onsager_coeff_negative_ion: Onsager transport coefficient of negative ions
• Debye_length: Debye screening length This causes the corresponding salt concentration to be specified automatically.

saltfree

• Valency_counterion: Valency of counter ions
• Onsager_coeff_counterion: {Onsager transport coefficient of counter ions

• Electric_field: type: ON: apply external electric field, OFF: no external electric field
  • ON: type: DC: apply steady electric field, AC: apply oscillatory electric field

  DC

  • Ex: Intensity of the x-direction electric field
  • Ey: Intensity of the y-direction electric field
  • Ez: Intensity of the z-direction electric field

  AC

  • Ex: Max intensity of the x-direction electric field
  • Ey: Max intensity of the y-direction electric field
  • Ez: Max intensity of the z-direction electric field
  • Frequency: Frequency of an oscillatory electric field.

object_type: type: {spherical_particle, chain}

spherical_particle

• Particle_spec[]
  • Particle_spec[0]: (0 means the 1st component)
    • Particle_number: Number of particles
    • MASS_RATIO: Density of particle / density of fluid
    • Surface_charge: Valency of particles (total charge carried by a single particle in unit of electron charge)

chain

• Chain_spec[]
  • Chain_spec[0] (0 meand the 1st component)
    • Beads_number: Number of beads in a single chain
    • Chain_number: Number of chains in a simulation box
    • MASS_RATIO: Density of beads / density of fluid
    • Surface_charge: Valency of beads (total charge carried by a single bead in unit of electron charge)

A_XI: Thickness of the particle-fluid boundary

A: Radius pd particles or beads

gravity

• G: Gravitational acceleration
• G_direction: -X , -Y , -Z: the direction in which gravity is applied

EPSILON: &color(foreground[,background]){text};

LJ_powers: {12:6, 24:12, 36:18}: &color(foreground[,background]){text};

mesh

• NPX: &color(foreground[,background]){text};
• NPY: &color(foreground[,background]){text};
• NPZ: &color(foreground[,background]){text};

time_increment: type: {auto, manual}: &color(foreground[,background]){text};

auto

• factor: &color(foreground[,background]){text};

manual

• delta_t: &color(foreground[,background]){text};

switch

• ROTATION: {ON, OFF}: &color(foreground[,background]){text};
• HYDRO_int: {Correct, free draining, squeeze-lubrication and drain}
• Stokes: {with advection, w/o advection}
• LJ_truncate: {ON, OFF, NONE}
• INIT_distribution: type: {uniform_random, random_walk, FCC, BCC, user_specify}

random_walk

• iteration

user_specify

• Particles[]
  • Particles[0]

    - R
      - x: 
      - y: 
      - z: 
    - v
      - x: 
      - y: 
      - z: 

FIX_CELL

• x: {ON, OFF}
• y: {ON, OFF}
• z: {ON, OFF}

boundary_condition: type: {z_dirichlet, full_periodic}

z_dirichlet

• wall_velocity_x:
• wall_velocity_y:
• wall_velocity_z:

output

• GTS:
• Num_snap:
• AVS: {ON, OFF}

ON

• Out_dir:
• Out_name:
• File_Type: {BINARY, ASCII}

• UDF: {ON, OFF}

E:

t:

Particles[]

• Particles[]

  - R
    - x: 
    - y: 
    - z: 
  - v
   - x: 
   - y: 
   - z: 

resume

• Calculation: {NEW, CONTINUE}