Page Menu
Home
c4science
Search
Configure Global Search
Log In
Files
F91974499
carbonation.cpp
No One
Temporary
Actions
Download File
Edit File
Delete File
View Transforms
Subscribe
Mute Notifications
Award Token
Subscribers
None
File Metadata
Details
File Info
Storage
Attached
Created
Sat, Nov 16, 07:21
Size
20 KB
Mime Type
text/x-c
Expires
Mon, Nov 18, 07:21 (2 d)
Engine
blob
Format
Raw Data
Handle
22355646
Attached To
rSPECMICP SpecMiCP / ReactMiCP
carbonation.cpp
View Options
#include <iostream>
#include "database/database.hpp"
#include "specmicp/reaction_path.hpp"
#include "reactmicp/mesh.hpp"
#include "reactmicp/systems/saturated_diffusion/reactive_transport_solver.hpp"
#include "reactmicp/systems/saturated_diffusion/transport_parameters.hpp"
#include "reactmicp/systems/saturated_diffusion/boundary_conditions.hpp"
#include "reactmicp/systems/saturated_diffusion/reactive_transport_neutrality_solver.hpp"
#include "reactmicp/systems/saturated_diffusion/transport_neutrality_parameters.hpp"
#include "utils/moving_average.hpp"
#include <fstream>
#include <Eigen/LU>
using
namespace
specmicp
;
using
namespace
specmicp
::
reactmicp
;
using
namespace
specmicp
::
reactmicp
::
systems
::
siasaturated
;
std
::
shared_ptr
<
database
::
DataContainer
>
set_database
()
{
specmicp
::
database
::
Database
database
(
"../data/cemdata_specmicp.js"
);
std
::
map
<
std
::
string
,
std
::
string
>
swapping
({
{
"H[+]"
,
"HO[-]"
},
{
"Si(OH)4"
,
"SiO(OH)3[-]"
},
});
database
.
swap_components
(
swapping
);
//std::vector<std::string> to_keep = {"H2O", "HO[-]", "Ca[2+]", "SiO(OH)3[-]", "HCO3[-]", "Al(OH)4[-]", "SO2"};
//database.keep_only_components(to_keep);
return
database
.
get_database
();
}
EquilibriumState
get_initial_state
(
std
::
shared_ptr
<
specmicp
::
database
::
DataContainer
>
database
,
double
mult
)
{
std
::
shared_ptr
<
specmicp
::
ReactionPathModel
>
model
=
std
::
make_shared
<
specmicp
::
ReactionPathModel
>
();
const
double
m_c3s
=
mult
*
0.7
;
const
double
m_c2s
=
mult
*
0.3
;
const
double
wc
=
1.0
;
const
double
m_water
=
wc
*
((
3
*
56.08
+
60.08
)
*
m_c3s
+
(
2
*
56.08
+
60.08
)
*
m_c2s
)
*
1e-3
;
model
->
amount_aqueous
=
{
{
"H2O"
,
specmicp
::
reaction_amount_t
(
m_water
/
database
->
molar_mass_basis_si
(
0
),
0.0
)},
{
"HO[-]"
,
specmicp
::
reaction_amount_t
(
-
1e-5
,
0.0
)},
{
"HCO3[-]"
,
specmicp
::
reaction_amount_t
(
1e-5
,
0.0
)}
};
model
->
amount_minerals
=
{
{
"C3S"
,
specmicp
::
reaction_amount_t
(
m_c3s
,
0.0
)},
{
"C2S"
,
specmicp
::
reaction_amount_t
(
m_c2s
,
0.0
)}
};
Eigen
::
VectorXd
x
;
specmicp
::
ReactionPathDriver
driver
(
model
,
database
,
x
);
//driver.get_options().solver_options.penalization_factor =1.0;
driver
.
get_options
().
ncp_function
=
specmicp
::
micpsolver
::
NCPfunction
::
penalizedFB
;
//driver.get_options().ncp_function = specmicp::micpsolver::NCPfunction::min;
driver
.
get_options
().
solver_options
.
use_scaling
=
false
;
driver
.
get_options
().
solver_options
.
max_factorization_step
=
1
;
driver
.
get_options
().
solver_options
.
factor_gradient_search_direction
=
50
;
driver
.
get_options
().
solver_options
.
maxstep
=
50
;
driver
.
get_options
().
solver_options
.
maxiter_maxstep
=
50
;
driver
.
get_options
().
solver_options
.
max_iter
=
100
;
driver
.
get_options
().
allow_restart
=
true
;
driver
.
get_options
().
system_options
.
charge_keeper
=
1
;
specmicp
::
micpsolver
::
MiCPPerformance
perf
=
driver
.
one_step
(
x
);
if
(
perf
.
return_code
!=
specmicp
::
micpsolver
::
MiCPSolverReturnCode
::
ResidualMinimized
)
throw
std
::
runtime_error
(
"Error - system cannot be solved"
);
return
driver
.
get_current_solution
();
}
EquilibriumState
get_blank_state
(
const
EquilibriumState
&
healthy_cp
)
{
specmicp
::
Vector
totconc
;
specmicp
::
RawDatabasePtr
thedatabase
=
healthy_cp
.
get_database
();
specmicp
::
Database
dbhandler
(
thedatabase
);
// healthy_cp.total_concentrations(totconc);
// index_t id_hco3 = dbhandler.component_label_to_id("HCO3[-]");
// index_t id_ca = dbhandler.component_label_to_id("Ca[2+]");
index_t
id_oh
=
dbhandler
.
component_label_to_id
(
"HO[-]"
);
// index_t id_ch = dbhandler.mineral_label_to_id("Portlandite");
// index_t id_csh = dbhandler.mineral_label_to_id("CSH,jennite");
// scalar_t addition =
// 2.5*(
// thedatabase->nu_mineral(id_ch, id_ca)*healthy_cp.moles_mineral(id_ch)
// + thedatabase->nu_mineral(id_csh, id_ca)*healthy_cp.moles_mineral(id_csh)
// );
// totconc(id_hco3) += addition;
// totconc(id_oh) -= addition;
// specmicp::Vector variables(healthy_cp.main_variables());
// specmicp::ReducedSystemSolver solver(thedatabase, totconc, healthy_cp);
// solver.get_options().system_options.charge_keeper = id_oh;
// specmicp::micpsolver::MiCPPerformance perf = solver.solve(variables);
// if (perf.return_code != specmicp::micpsolver::MiCPSolverReturnCode::ResidualMinimized)
// throw std::runtime_error("Error - blank system cannot be solved");
// return solver.get_solution(variables);
std
::
shared_ptr
<
specmicp
::
ReactionPathModel
>
model
=
std
::
make_shared
<
specmicp
::
ReactionPathModel
>
();
//const double m_c3s = 1e-8;
const
double
m_c2s
=
1e-6
;
const
double
m_water
=
1.0
;
model
->
amount_aqueous
=
{
{
"H2O"
,
specmicp
::
reaction_amount_t
(
m_water
/
thedatabase
->
molar_mass_basis_si
(
0
),
0.0
)},
// {"HO[-]", specmicp::reaction_amount_t(-0.2, 0.0)},
// {"SiO(OH)3[-]", specmicp::reaction_amount_t(0.0, 0.0)},
// {"HCO3[-]", specmicp::reaction_amount_t(0.2, 0.0)}
};
model
->
amount_minerals
=
{
//{"C3S", specmicp::reaction_amount_t(m_c3s, 0.0)},
{
"C2S"
,
specmicp
::
reaction_amount_t
(
m_c2s
,
0.0
)},
{
"SiO2,am"
,
specmicp
::
reaction_amount_t
(
1e-2
,
0.0
)},
{
"Calcite"
,
specmicp
::
reaction_amount_t
(
1e-2
,
0.0
)}
};
Eigen
::
VectorXd
x
(
thedatabase
->
nb_component
+
thedatabase
->
nb_mineral
);
x
.
setZero
();
x
(
0
)
=
1.0
;
x
.
segment
(
1
,
thedatabase
->
nb_component
-
1
).
setConstant
(
-
6
);
specmicp
::
ReactionPathDriver
driver
(
model
,
thedatabase
,
x
);
driver
.
get_options
().
solver_options
.
penalization_factor
=
1.0
;
driver
.
get_options
().
ncp_function
=
specmicp
::
micpsolver
::
NCPfunction
::
penalizedFB
;
//driver.get_options().ncp_function = specmicp::micpsolver::NCPfunction::min;
driver
.
get_options
().
solver_options
.
use_scaling
=
false
;
driver
.
get_options
().
solver_options
.
max_factorization_step
=
1
;
driver
.
get_options
().
solver_options
.
factor_gradient_search_direction
=
50
;
driver
.
get_options
().
solver_options
.
maxstep
=
50
;
driver
.
get_options
().
solver_options
.
maxiter_maxstep
=
50
;
driver
.
get_options
().
solver_options
.
max_iter
=
100
;
driver
.
get_options
().
system_options
.
charge_keeper
=
id_oh
;
driver
.
get_options
().
allow_restart
=
true
;
specmicp
::
micpsolver
::
MiCPPerformance
perf
=
driver
.
one_step
(
x
);
if
(
perf
.
return_code
!=
specmicp
::
micpsolver
::
MiCPSolverReturnCode
::
ResidualMinimized
)
throw
std
::
runtime_error
(
"Error - blank system cannot be solved"
);
EquilibriumState
solution
=
driver
.
get_current_solution
();
std
::
cout
<<
solution
.
main_variables
()
<<
std
::
endl
;
return
solution
;
}
int
carbonation
()
{
//Vector compo_oxyde(4), compo_species(4);
//compo_oxyde << 62.9, 20.6, 5.8, 3.1;
//compo_from_oxyde(compo_oxyde, compo_species);
std
::
shared_ptr
<
database
::
DataContainer
>
thedatabase
=
set_database
();
scalar_t
radius
=
3.5
;
//cm
scalar_t
height
=
8.0
;
//cm
scalar_t
dx
=
0.005
;
index_t
additional_nodes
=
1
;
radius
=
radius
+
additional_nodes
*
dx
;
index_t
nb_nodes
=
100
;
utils
::
ExponentialMovingAverage
averager1
(
0.001
,
5
);
utils
::
ExponentialMovingAverage
averager2
(
0.01
,
5
);
utils
::
ExponentialMovingAverage
averager3
(
0.1
,
5
);
mesh
::
Mesh1DPtr
themesh
=
mesh
::
axisymmetric_uniform_mesh1d
(
nb_nodes
,
radius
,
dx
,
height
);
std
::
shared_ptr
<
SaturatedDiffusionTransportParameters
>
parameters
=
std
::
make_shared
<
SaturatedDiffusionTransportParameters
>
(
nb_nodes
,
1e4
*
std
::
exp
(
9.95
*
0.25
-
29.08
),
0.25
);
parameters
->
diffusion_coefficient
(
0
)
=
2.2e-5
;
// cm^2/s
parameters
->
porosity
(
0
)
=
1.0
;
EquilibriumState
initial_state
=
get_initial_state
(
thedatabase
,
0.5
);
SIABoundaryConditions
bcs
(
nb_nodes
);
bcs
.
list_initial_states
.
push_back
(
initial_state
);
bcs
.
list_initial_states
.
push_back
(
get_blank_state
(
initial_state
));
bcs
.
bs_types
[
0
]
=
BoundaryConditionType
::
FixedComposition
;
//bcs.initial_states[0] = 1;
for
(
index_t
node
=
0
;
node
<
additional_nodes
;
++
node
)
bcs
.
initial_states
[
node
]
=
1
;
database
::
Database
dbhandler
(
thedatabase
);
index_t
id_ca
=
dbhandler
.
component_label_to_id
(
"Ca[2+]"
);
index_t
id_si
=
dbhandler
.
component_label_to_id
(
"SiO(OH)3[-]"
);
index_t
id_oh
=
dbhandler
.
component_label_to_id
(
"HO[-]"
);
index_t
id_co2
=
dbhandler
.
component_label_to_id
(
"HCO3[-]"
);
for
(
index_t
mineral:
thedatabase
->
range_mineral
())
{
std
::
cout
<<
thedatabase
->
labels_minerals
[
mineral
]
<<
std
::
endl
;
}
std
::
cout
<<
"Volume first cell "
<<
themesh
->
get_volume_cell
(
additional_nodes
)
<<
std
::
endl
;
//return EXIT_SUCCESS;
std
::
ofstream
output_ca
,
output_aqca
,
output_si
,
output_poro
,
output_ph
;
std
::
ofstream
output_saca
,
output_sasi
;
std
::
ofstream
output_co2
,
output_aqco2
,
output_sa_co2
;
std
::
ofstream
output_iter
;
output_ca
.
open
(
"out_ca.dat"
);
output_aqca
.
open
(
"out_aqca.dat"
);
output_si
.
open
(
"out_si.dat"
);
output_ph
.
open
(
"out_ph.dat"
);
output_poro
.
open
(
"out_poro.dat"
);
output_saca
.
open
(
"out_sa_ca.dat"
);
output_sasi
.
open
(
"out_sa_si.dat"
);
output_iter
.
open
(
"nb_iter.dat"
);
output_co2
.
open
(
"out_co2.dat"
);
output_aqco2
.
open
(
"out_aqco2.dat"
);
output_sa_co2
.
open
(
"out_sa_co2.dat"
);
std
::
vector
<
std
::
ofstream
>
mineral_out
(
thedatabase
->
nb_mineral
);
for
(
int
mineral:
thedatabase
->
range_mineral
())
{
mineral_out
[
mineral
].
open
(
"out_mineral_"
+
std
::
to_string
(
mineral
)
+
".dat"
);
}
SIASaturatedReactiveTransportSolver
solver
(
themesh
,
thedatabase
,
parameters
);
solver
.
apply_boundary_conditions
(
bcs
);
solver
.
get_variables
().
scale_volume
();
//solver.use_snia();
solver
.
use_sia
(
500
);
solver
.
get_options
().
residual_tolerance
=
1e-2
;
solver
.
get_options
().
absolute_residual_tolerance
=
1e-8
;
solver
.
get_options
().
threshold_update_disable_speciation
=
1e-20
;
solver
.
get_options
().
threshold_update_transport
=
1e-10
;
solver
.
get_options
().
good_enough_transport_residual_tolerance
=
1.0
;
solver
.
get_options
().
relative_update
=
1e-6
;
solver
.
get_options
().
use_consistent_velocity
=
true
;
solver
.
get_options
().
use_previous_flux
=
false
;
// Transport
solver
.
get_options
().
transport_options
.
residuals_tolerance
=
1e-8
;
solver
.
get_options
().
transport_options
.
maximum_iterations
=
500
;
solver
.
get_options
().
transport_options
.
step_tolerance
=
1e-8
;
solver
.
get_options
().
transport_options
.
threshold_stationary_point
=
1e-5
;
solver
.
get_options
().
transport_options
.
quasi_newton
=
3
;
solver
.
get_options
().
transport_options
.
sparse_solver
=
SparseSolver
::
SparseLU
;
solver
.
get_options
().
transport_options
.
maximum_step_length
=
1e4
;
//solver.get_options().transport_options.alpha = 0.0;
solver
.
get_options
().
transport_options
.
linesearch
=
dfpmsolver
::
ParabolicLinesearch
::
Strang
;
// Speciation
solver
.
get_options
().
speciation_options
.
system_options
.
charge_keeper
=
1
;
solver
.
get_options
().
speciation_options
.
system_options
.
conservation_water
=
true
;
solver
.
get_options
().
speciation_options
.
system_options
.
non_ideality
=
true
;
solver
.
get_options
().
speciation_options
.
solver_options
.
fvectol
=
1e-12
;
solver
.
get_options
().
speciation_options
.
system_options
.
non_ideality_tolerance
=
1e-14
;
solver
.
get_options
().
speciation_options
.
solver_options
.
use_crashing
=
false
;
solver
.
get_options
().
speciation_options
.
solver_options
.
use_scaling
=
false
;
solver
.
get_options
().
speciation_options
.
solver_options
.
max_iter
=
100
;
solver
.
get_options
().
speciation_options
.
solver_options
.
maxstep
=
40
;
solver
.
get_options
().
speciation_options
.
solver_options
.
non_monotone_linesearch
=
true
;
solver
.
get_options
().
speciation_options
.
solver_options
.
threshold_cycling_linesearch
=
1e-8
;
solver
.
get_options
().
speciation_options
.
solver_options
.
steptol
=
1e-16
;
solver
.
get_options
().
speciation_options
.
solver_options
.
threshold_stationary_point
=
1e-4
;
std
::
cout
<<
"id SiO2,am : "
<<
dbhandler
.
mineral_label_to_id
(
"SiO2,am"
)
<<
std
::
endl
;
//thedatabase->stability_mineral(
// dbhandler.mineral_label_to_id("SiO2,am")) = database::MineralStabilityClass::cannot_dissolve;
SIASaturatedVariables
&
first_variables
=
solver
.
get_variables
();
std
::
cout
<<
first_variables
.
total_mobile_concentrations
()
<<
std
::
endl
;
//double dt = 5e4;
double
total
=
0
;
uindex_t
k
=
0
;
scalar_t
dt
=
10.0
;
scalar_t
dt_min
=
1.0
;
scalar_t
dt_max
=
10.0
;
uindex_t
max_iter
;
while
(
total
<
365
*
24
*
3600
)
{
total
+=
dt
;
std
::
cout
<<
" iterations : "
<<
k
<<
" - dt : "
<<
dt
<<
" - total : "
<<
total
/
24
/
3600
<<
std
::
endl
;
//start_again:
SIASaturatedReactiveTransportSolverReturnCode
retcode
=
solver
.
solve_timestep
(
dt
);
std
::
cout
<<
" Return code : "
<<
(
int
)
retcode
<<
" - Nb iter : "
<<
solver
.
get_perfs
().
nb_iterations
<<
std
::
endl
<<
" - Nb iter transport : "
<<
solver
.
get_perfs
().
nb_iterations_transport
<<
std
::
endl
<<
" - Nb iter chemistry : "
<<
solver
.
get_perfs
().
nb_iterations_chemistry
<<
std
::
endl
;
if
(
retcode
!=
SIASaturatedReactiveTransportSolverReturnCode
::
Success
)
{
if
(
false
and
retcode
==
SIASaturatedReactiveTransportSolverReturnCode
::
MaxIterations
)
{
max_iter
+=
1
;
ERROR
<<
"Maximum iterations"
;
}
else
{
std
::
cout
<<
"Current residual : "
<<
solver
.
get_perfs
().
current_residual
<<
std
::
endl
;
SIASaturatedVariables
&
variables
=
solver
.
get_variables
();
output_ca
<<
total
<<
" "
<<
total
/
(
3600.0
*
24.0
);
output_aqca
<<
total
<<
" "
<<
total
/
(
3600.0
*
24.0
);
output_si
<<
total
<<
" "
<<
total
/
(
3600.0
*
24.0
);
output_poro
<<
total
<<
" "
<<
total
/
(
3600.0
*
24.0
);
output_ph
<<
total
<<
" "
<<
total
/
(
3600.0
*
24.0
);
output_saca
<<
total
<<
" "
<<
total
/
(
3600.0
*
24.0
);
output_sasi
<<
total
<<
" "
<<
total
/
(
3600.0
*
24.0
);
for
(
index_t
node:
themesh
->
range_nodes
())
{
output_ca
<<
" "
<<
variables
.
nodal_component_update_total_amount
(
node
,
id_ca
);
output_aqca
<<
" "
<<
variables
.
total_mobile_concentration
(
node
,
id_ca
);
output_si
<<
" "
<<
variables
.
nodal_component_update_total_amount
(
node
,
id_si
);
output_ph
<<
" "
<<
14
+
variables
.
log_gamma_component
(
node
,
id_oh
)
+
variables
.
log_component_concentration
(
node
,
id_oh
);
double
volume
=
variables
.
volume_minerals
(
node
);
double
cell_volume
=
themesh
->
get_volume_cell
(
node
);
output_poro
<<
" "
<<
(
cell_volume
-
volume
*
1e6
)
/
cell_volume
;
output_saca
<<
" "
<<
variables
.
component_concentration_in_minerals
(
node
,
id_ca
);
output_sasi
<<
" "
<<
variables
.
component_concentration_in_minerals
(
node
,
id_si
);
}
output_ca
<<
std
::
endl
;
output_aqca
<<
std
::
endl
;
output_si
<<
std
::
endl
;
output_poro
<<
std
::
endl
;
output_ph
<<
std
::
endl
;
output_saca
<<
std
::
endl
;
output_sasi
<<
std
::
endl
;
output_ca
.
close
();
output_aqca
.
close
();
output_si
.
close
();
output_poro
.
close
();
output_saca
.
close
();
output_sasi
.
close
();
throw
std
::
runtime_error
(
"Failed to converge : "
+
std
::
to_string
((
int
)
retcode
));
}
}
//if (solver.get_perfs().nb_iterations <= 10) dt*=1.1;
SIASaturatedVariables
&
variables
=
solver
.
get_variables
();
//std::cout << variables.total_mobile_concentrations() << std::endl;
// compute porosity
for
(
index_t
node:
themesh
->
range_nodes
())
{
double
volume
=
variables
.
volume_minerals
(
node
);
double
cell_volume
=
themesh
->
get_volume_cell
(
node
);
specmicp_assert
(
volume
<
cell_volume
);
double
porosity
=
(
cell_volume
-
volume
*
1e6
)
/
cell_volume
;
parameters
->
porosity
(
node
)
=
porosity
;
//parameters->diffusion_coefficient(node) =
// std::max(porosity>0.92?2.219e-5:1e4*std::exp(9.95*porosity-29.08), 2e-8);
}
std
::
cout
<<
variables
.
component_concentration
(
1
,
id_ca
)
<<
std
::
endl
;
parameters
->
diffusion_coefficient
(
0
)
=
2.219e-5
;
// parameters->diffusion_coefficient(1);
//if (solver.get_perfs().nb_iterations > 15) dt = 0.95*dt;
//else if (solver.get_perfs().nb_iterations < 2) dt = 1.05*dt;
output_iter
<<
k
<<
" "
<<
solver
.
get_perfs
().
nb_iterations
<<
" "
<<
solver
.
get_perfs
().
current_residual
<<
" "
<<
averager1
.
add_point
(
solver
.
get_perfs
().
nb_iterations
)
<<
" "
<<
averager2
.
add_point
(
solver
.
get_perfs
().
nb_iterations
)
<<
" "
<<
averager3
.
add_point
(
solver
.
get_perfs
().
nb_iterations
)
<<
std
::
endl
;
//std::cout << variables.speciation_variables() << std::endl;
if
(
k
==
1
or
(
k
<
1000
and
k
%
100
==
0
)
or
k
%
1000
==
0
)
{
output_ca
<<
total
<<
" "
<<
total
/
(
3600.0
*
24.0
);
output_aqca
<<
total
<<
" "
<<
total
/
(
3600.0
*
24.0
);
output_saca
<<
total
<<
" "
<<
total
/
(
3600.0
*
24.0
);
output_si
<<
total
<<
" "
<<
total
/
(
3600.0
*
24.0
);
output_sasi
<<
total
<<
" "
<<
total
/
(
3600.0
*
24.0
);
output_co2
<<
total
<<
" "
<<
total
/
(
3600.0
*
24.0
);
output_aqco2
<<
total
<<
" "
<<
total
/
(
3600.0
*
24.0
);
output_sa_co2
<<
total
<<
" "
<<
total
/
(
3600.0
*
24.0
);
output_poro
<<
total
<<
" "
<<
total
/
(
3600.0
*
24.0
);
output_ph
<<
total
<<
" "
<<
total
/
(
3600.0
*
24.0
);
for
(
index_t
node:
themesh
->
range_nodes
())
{
output_ca
<<
" "
<<
variables
.
nodal_component_update_total_amount
(
node
,
id_ca
);
output_aqca
<<
" "
<<
variables
.
total_mobile_concentration
(
node
,
id_ca
);
output_saca
<<
" "
<<
variables
.
component_concentration_in_minerals
(
node
,
id_ca
);
output_sasi
<<
" "
<<
variables
.
component_concentration_in_minerals
(
node
,
id_si
);
output_si
<<
" "
<<
variables
.
nodal_component_update_total_amount
(
node
,
id_si
);
output_co2
<<
" "
<<
variables
.
nodal_component_update_total_amount
(
node
,
id_co2
);
output_aqco2
<<
" "
<<
variables
.
total_mobile_concentration
(
node
,
id_co2
);
output_sa_co2
<<
" "
<<
variables
.
component_concentration_in_minerals
(
node
,
id_co2
);
output_ph
<<
" "
<<
14
+
variables
.
log_gamma_component
(
node
,
id_oh
)
+
variables
.
log_component_concentration
(
node
,
id_oh
);
double
volume
=
variables
.
volume_minerals
(
node
);
double
cell_volume
=
themesh
->
get_volume_cell
(
node
);
output_poro
<<
" "
<<
(
cell_volume
-
volume
*
1e6
)
/
cell_volume
;
}
output_ca
<<
std
::
endl
;
output_aqca
<<
std
::
endl
;
output_saca
<<
std
::
endl
;
output_si
<<
std
::
endl
;
output_sasi
<<
std
::
endl
;
output_co2
<<
std
::
endl
;
output_aqco2
<<
std
::
endl
;
output_sa_co2
<<
std
::
endl
;
output_poro
<<
std
::
endl
;
output_ph
<<
std
::
endl
;
for
(
index_t
mineral:
thedatabase
->
range_mineral
())
{
mineral_out
[
mineral
]
<<
total
<<
" "
<<
total
/
(
3600.0
*
24.0
);
for
(
index_t
node:
themesh
->
range_nodes
())
{
mineral_out
[
mineral
]
<<
" "
<<
variables
.
mineral_amount
(
node
,
mineral
);
}
mineral_out
[
mineral
]
<<
std
::
endl
;
}
}
++
k
;
if
((
averager3
.
current_value
()
-
averager1
.
current_value
())
>
10
)
{
dt
=
std
::
max
(
dt
*
0.95
,
dt_min
);
averager1
.
reset
(
averager3
.
current_value
());
}
if
((
averager2
.
current_value
()
-
averager3
.
current_value
())
>
10
)
{
dt
=
std
::
min
(
dt
*
1.5
,
dt_max
);
averager2
.
reset
(
averager3
.
current_value
());
}
}
output_iter
.
close
();
output_ca
.
close
();
output_aqca
.
close
();
output_si
.
close
();
output_poro
.
close
();
output_saca
.
close
();
output_sasi
.
close
();
for
(
index_t
mineral:
thedatabase
->
range_mineral
())
{
mineral_out
[
mineral
].
close
();
}
std
::
cout
<<
"Max iterations : "
<<
max_iter
<<
std
::
endl
;
return
EXIT_SUCCESS
;
}
int
main
()
{
specmicp
::
stdlog
::
ReportLevel
()
=
specmicp
::
logger
::
Warning
;
specmicp
::
logger
::
ErrFile
::
stream
()
=
&
std
::
cerr
;
carbonation
();
}
Event Timeline
Log In to Comment