T005_AlSi_trapping.log

 MICRESS binary
 **************
 version number: 6.400 (Linux)
 compiled: 01/17/2018
 compiler version: Intel 1400 20140120
 executable architecture: x64
 Thermo-Calc coupling: enabled
 #    Version:    19
 #    Link Date:  20-03-2017 12:28:00
 #    OS Name:    Linux
 #    Build Date: 10716
 #    Compiler:   ifort (IFORT) 14.0.2 20140120
 OpenMP: disabled
 shell: /bin/tcsh
 ('double precision' binary)

 Miscellanea
 ***********
 Date and time: 17/01/2018 (04:05)
 Machine: n009
 Driving file: T005_AlSi_trapping_dri.temp


 Flags and settings
 ******************

 Geometry
 --------
 AnzX,   AnzY,   AnzZ   = 1, 1, 250
 deltaX, deltaY, deltaZ [cm] = 2.5000E-05, 2.5000E-05, 2.5000E-05

 Flags
 -----
 Simulation with concentration coupling
 'Multi-obstacle' potential
 no_1d_far_field
 no_1d_temp
 IFaceDim coeff. : 0.100 (0.75, 0.50)
 nTupelDim coeff.: 0.100 (0.75, 0.50)


 The data compression is done with 'zlib' (cf. http://www.zlib.net/).
 The routine for appending is loosely derived from the 'gzappend.c' example.


 Time input data
 ***************
 Number of intermediate outputs = 20
 Intermediate output at t       = 2.0000000E-01 s
 Intermediate output at t       = 4.0000000E-01 s
 Intermediate output at t       = 6.0000000E-01 s
 Intermediate output at t       = 8.0000000E-01 s
 Intermediate output at t       = 1.0000000E+00 s
 Intermediate output at t       = 1.2000000E+00 s
 Intermediate output at t       = 1.4000000E+00 s
 Intermediate output at t       = 1.6000000E+00 s
 Intermediate output at t       = 1.8000000E+00 s
 Intermediate output at t       = 2.0000000E+00 s
 Intermediate output at t       = 2.2000000E+00 s
 Intermediate output at t       = 2.4000000E+00 s
 Intermediate output at t       = 2.6000000E+00 s
 Intermediate output at t       = 2.8000000E+00 s
 Intermediate output at t       = 3.0000000E+00 s
 Intermediate output at t       = 3.2000000E+00 s
 Intermediate output at t       = 3.4000000E+00 s
 Intermediate output at t       = 3.6000000E+00 s
 Intermediate output at t       = 3.8000000E+00 s
 Intermediate output at t       = 4.0000000E+00 s
 Coefficient for phase-field criterion 1.00
 Coefficient for segregation criterion 0.950
 Upper limit for time step: 0.100
 Lower limit for time step: 1.000E-12
 Number of steps to adjust profiles of initially sharp interfaces [exclude_inactive]: 30
 
 
 Phase data
 **********
 Number of distinct solid phases = 1
 
 Data for phase 1:
 -----------------
 in phase 1, recrystallisation will not be considered.
 Phase 1 is isotropic.
 No categorization is allowed for phase 1


 Grain input
 ***********
 Grains will be positioned deterministically
 Number of grains = 1
 Input data for grain number 1:
  'Rectangular' grain.
  x,z coordinates               : 0.00000, 0.00000 micrometers
  Length along X,Z axis         : 2.00000, 30.0000 micrometers
  No Voronoi construction
  Phase number                  : 1


 Data for further nucleation
 ***************************
 Run-time nucleation disabled
 
 
 Phase interaction data
 **********************
 
 Data for phase interaction 0 / 1:
 ---------------------------------
  Interaction between 0 and 1 will be simulated.
  Interaction parameters between phases  0  and 1:
  Averaging coefficient        Av = +0.50
  Interfacial energy        sigma = 1.00000E-04 [J/cm**2]
  Kinetic coefficient          mu = 2.00000E-03 [cm**4/(Js)]
 
 Data for phase interaction 1 / 1:
 ---------------------------------
  Interaction between 1 and 1 will not be simulated.


 Concentration data
 ******************
 Number of dissolved constituents = 1
 Concentration in weight percent wt%

 Diffusion Data
 --------------
 Diffusion of component 1  in phase 0  will be solved.
 Diff.-coefficient:
 Prefactor: 1.340000000000000E-003 [cm**2/s]
 Activation energy: 30000.0000000000 [J/mol]
 Diffusion of component 1  in phase 1  will not be solved.


 Phase diagram - input data
 **************************

 TC-Coupling is not performed

 Input of the phase diagram of phase 0 and phase 1:
 --------------------------------------------------
 Linear phase diagram is used
  Temperature of the cut = 933.470800000000 K
  conc0( 0: 1: 1) = 0.00000E+00 [wt%]
  conc0( 1: 0: 1) = 0.00000E+00 [wt%]
  Slope       mSlope( 1: 0: 1) = -5.75736E+01 K/wt%
  Slope       mSlope( 0: 1: 1) = -6.05282E+00 K/wt%
 Redistribution characteristics of components:
 1:  normal normal
 
 
 Initial concentrations
 **********************
 Concentrations will be automatically set, matrix phase: 0
 Initial concentration of component 1 in phase 0 = 1.000000000 wt%


 Parameters for latent heat and 1D temperature field
 ***************************************************
 Simulation without release of latent heat
 
 
 Boundary conditions
 *******************
 Initial temperature at the bottom: 880.0000 K
 Temperature gradient at beginning: 0.0000 K/cm
 Cooling rate: 0.0000 K/s
 Simulation domain shifted in z-direction
 minimal distance to the upper boundary MovingFrameDist = 44.25000 micrometer
 Data shifted out from moving-frame system will not be stored
 
 In W-direction isolation boundary condition for phase field
 In E-direction isolation boundary condition for phase field
 In B-direction isolation boundary condition for phase field
 In T-direction isolation boundary condition for phase field
 
 In W-direction isolation boundary condition for concentration field
 In E-direction isolation boundary condition for concentration field
 In B-direction isolation boundary condition for concentration field
 In T-direction fixed boundary condition for concentration field
 Fixed value for concentration field for component 1 in T-direction 1.00000 wt%
 
 Unit-cell model symmetric with respect to the x/y diagonal plane not activated


 Other numerical parameters
 **************************
 Phase minimum      phMin = 1.00E-04
 Interface thickness etaZ = 6.00000000000000


 Beginning of initialisation
 ***************************
 # Grain number 1 set
 Equilibrium temperature T_Glgew = 927.4180 K
 Phase  0, Component  0: 99.00000
 Phase  0, Component  1: 1.000000
 Phase  1, Component  0: 99.89487
 Phase  1, Component  1:0.1051319
 
 # tWidth_max( 0 : 1 ) = 1.4843750E-03 s
 # Maximal value for tWidth = 1.4843750E-03 s for phase-field solver
 # Maximal value for tWidth = 1.3370581E-05 s for conc-field solver
 # Automatic time stepping (phase-field solver): decreased value for tWidth = 1.27021E-05 s
 # Initial value for tWidth = 1.27021E-05 s for automatic time stepping (phase-field solver)
 # Critical grain radius:
 # of phase 1 in phase 0 = 0.87146 / dT_unt  [micrometers]
 
 Remaining license time: permanent

 ==================================================

 Time t = 0.0000000 s
 CPU-time: 0 s
 Current phase-field solver time step = 1.27E-05 s
 Average conc. of comp. 1 = 0.7852317 wt%
 Temperature at the bottom = 880.00 K
 Temperature gradient = 0.00000 K/cm
 Fraction of phase 0: 0.76000
 Fraction of phase 1: 0.24000

 **********************************************
 *         Beginning of simulation            *
 **********************************************

 Intermediate output for t = 0.20000 s
 CPU-time: 1 s
 Current phase-field solver time step = 3.37E-05 s
 Average conc. of comp. 1 = 1.4363195 wt%
 Temperature at the bottom = 880.00 K
 Temperature gradient = 0.00000 K/cm
 Simulation area shifted by 381 layers
 Velocity of the comoving frame = 0.4763E-01 cm/s

 Intermediate output for t = 0.40000 s
 CPU-time: 0 s
 Current phase-field solver time step = 4.20E-05 s
 Average conc. of comp. 1 = 1.6293124 wt%
 Temperature at the bottom = 880.00 K
 Temperature gradient = 0.00000 K/cm
 Simulation area shifted by 638 layers
 Velocity of the comoving frame = 0.3213E-01 cm/s

 Intermediate output for t = 0.60000 s
 CPU-time: 0 s
 Current phase-field solver time step = 4.71E-05 s
 Average conc. of comp. 1 = 1.7533244 wt%
 Temperature at the bottom = 880.00 K
 Temperature gradient = 0.00000 K/cm
 Simulation area shifted by 856 layers
 Velocity of the comoving frame = 0.2725E-01 cm/s

 Intermediate output for t = 0.80000 s
 CPU-time: 0 s
 Current phase-field solver time step = 5.08E-05 s
 Average conc. of comp. 1 = 1.8400487 wt%
 Temperature at the bottom = 880.00 K
 Temperature gradient = 0.00000 K/cm
 Simulation area shifted by 1053 layers
 Velocity of the comoving frame = 0.2463E-01 cm/s

 Intermediate output for t = 1.0000 s
 CPU-time: 0 s
 Current phase-field solver time step = 5.44E-05 s
 Average conc. of comp. 1 = 1.9024757 wt%
 Temperature at the bottom = 880.00 K
 Temperature gradient = 0.00000 K/cm
 Simulation area shifted by 1238 layers
 Velocity of the comoving frame = 0.2313E-01 cm/s

 Intermediate output for t = 1.2000 s
 CPU-time: 0 s
 Current phase-field solver time step = 5.61E-05 s
 Average conc. of comp. 1 = 1.9470394 wt%
 Temperature at the bottom = 880.00 K
 Temperature gradient = 0.00000 K/cm
 Simulation area shifted by 1414 layers
 Velocity of the comoving frame = 0.2200E-01 cm/s

 Intermediate output for t = 1.4000 s
 CPU-time: 0 s
 Current phase-field solver time step = 5.83E-05 s
 Average conc. of comp. 1 = 1.9792926 wt%
 Temperature at the bottom = 880.00 K
 Temperature gradient = 0.00000 K/cm
 Simulation area shifted by 1585 layers
 Velocity of the comoving frame = 0.2138E-01 cm/s

 Intermediate output for t = 1.6000 s
 CPU-time: 0 s
 Current phase-field solver time step = 5.90E-05 s
 Average conc. of comp. 1 = 2.0019329 wt%
 Temperature at the bottom = 880.00 K
 Temperature gradient = 0.00000 K/cm
 Simulation area shifted by 1751 layers
 Velocity of the comoving frame = 0.2075E-01 cm/s

 Intermediate output for t = 1.8000 s
 CPU-time: 0 s
 Current phase-field solver time step = 5.96E-05 s
 Average conc. of comp. 1 = 2.0183067 wt%
 Temperature at the bottom = 880.00 K
 Temperature gradient = 0.00000 K/cm
 Simulation area shifted by 1915 layers
 Velocity of the comoving frame = 0.2050E-01 cm/s

 Intermediate output for t = 2.0000 s
 CPU-time: 0 s
 Current phase-field solver time step = 6.14E-05 s
 Average conc. of comp. 1 = 2.0299666 wt%
 Temperature at the bottom = 880.00 K
 Temperature gradient = 0.00000 K/cm
 Simulation area shifted by 2077 layers
 Velocity of the comoving frame = 0.2025E-01 cm/s

 Intermediate output for t = 2.2000 s
 CPU-time: 0 s
 Current phase-field solver time step = 5.99E-05 s
 Average conc. of comp. 1 = 2.0379020 wt%
 Temperature at the bottom = 880.00 K
 Temperature gradient = 0.00000 K/cm
 Simulation area shifted by 2237 layers
 Velocity of the comoving frame = 0.2000E-01 cm/s

 Intermediate output for t = 2.4000 s
 CPU-time: 0 s
 Current phase-field solver time step = 6.11E-05 s
 Average conc. of comp. 1 = 2.0438705 wt%
 Temperature at the bottom = 880.00 K
 Temperature gradient = 0.00000 K/cm
 Simulation area shifted by 2397 layers
 Velocity of the comoving frame = 0.2000E-01 cm/s

 Intermediate output for t = 2.6000 s
 CPU-time: 0 s
 Current phase-field solver time step = 6.12E-05 s
 Average conc. of comp. 1 = 2.0479973 wt%
 Temperature at the bottom = 880.00 K
 Temperature gradient = 0.00000 K/cm
 Simulation area shifted by 2556 layers
 Velocity of the comoving frame = 0.1987E-01 cm/s

 Intermediate output for t = 2.8000 s
 CPU-time: 0 s
 Current phase-field solver time step = 6.16E-05 s
 Average conc. of comp. 1 = 2.0511572 wt%
 Temperature at the bottom = 880.00 K
 Temperature gradient = 0.00000 K/cm
 Simulation area shifted by 2715 layers
 Velocity of the comoving frame = 0.1987E-01 cm/s

 Intermediate output for t = 3.0000 s
 CPU-time: 0 s
 Current phase-field solver time step = 6.13E-05 s
 Average conc. of comp. 1 = 2.0531212 wt%
 Temperature at the bottom = 880.00 K
 Temperature gradient = 0.00000 K/cm
 Simulation area shifted by 2873 layers
 Velocity of the comoving frame = 0.1975E-01 cm/s

 Intermediate output for t = 3.2000 s
 CPU-time: 0 s
 Current phase-field solver time step = 6.17E-05 s
 Average conc. of comp. 1 = 2.0545652 wt%
 Temperature at the bottom = 880.00 K
 Temperature gradient = 0.00000 K/cm
 Simulation area shifted by 3031 layers
 Velocity of the comoving frame = 0.1975E-01 cm/s

 Intermediate output for t = 3.4000 s
 CPU-time: 0 s
 Current phase-field solver time step = 6.18E-05 s
 Average conc. of comp. 1 = 2.0557051 wt%
 Temperature at the bottom = 880.00 K
 Temperature gradient = 0.00000 K/cm
 Simulation area shifted by 3189 layers
 Velocity of the comoving frame = 0.1975E-01 cm/s

 Intermediate output for t = 3.6000 s
 CPU-time: 0 s
 Current phase-field solver time step = 6.06E-05 s
 Average conc. of comp. 1 = 2.0560718 wt%
 Temperature at the bottom = 880.00 K
 Temperature gradient = 0.00000 K/cm
 Simulation area shifted by 3346 layers
 Velocity of the comoving frame = 0.1962E-01 cm/s

 Intermediate output for t = 3.8000 s
 CPU-time: 0 s
 Current phase-field solver time step = 6.15E-05 s
 Average conc. of comp. 1 = 2.0568188 wt%
 Temperature at the bottom = 880.00 K
 Temperature gradient = 0.00000 K/cm
 Simulation area shifted by 3504 layers
 Velocity of the comoving frame = 0.1975E-01 cm/s

 Intermediate output for t = 4.0000 s
 CPU-time: 0 s
 Current phase-field solver time step = 6.25E-05 s
 Average conc. of comp. 1 = 2.0573714 wt%
 Temperature at the bottom = 880.00 K
 Temperature gradient = 0.00000 K/cm
 Simulation area shifted by 3662 layers
 Velocity of the comoving frame = 0.1975E-01 cm/s

 ==================================================

 Simulation run on machine n009
 Remaining license time: permanent
 CPU time in seconds:          16
 Wall clock time in seconds:  355
 End