output{ }¶
- Calling sequence
output{ }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
items: \(\mathrm{maximum\;1}\)
- Functionality
Sets options for the output data and controls additional output of material parameters.
- Example
output{...}
Nested keywords
directory¶
- Calling sequence
output{ directory }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{character\;string}\)
- Functionality
Defines alternative output directory. Using this path is controlled by mandatory_path
- Example
output{ directory = "../output/the_best_simulation" }
mandatory_path¶
- Calling sequence
output{ mandatory_path }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{choice}\)
choices:
yes
;no
default:
no
- Functionality
If
mandatory_path = yes
then the (relative or absolute) output directory specified by directory is used, and any directory specified in the command line is ignored (as, e.g., done by nextnanomat).If
mandatory_path = no
then the directory specified in the command line is used as base path to which a relative path specified in directory then is appended. In this case an absolute path specified in directory is ignored.In all cases, a subdirectory named as the input file is further appended to the output path, unless
-n
or--noautooutdir
is set as command line option (nextnanomat sets this option automatically).Also note that the location of the log (
*.log
) file is not affected by these settings.
Warning
Please make sure that a mandatory output directory is set such that no important files (or the input directory) are overwritten. Be especially careful when accepting input files from others, and do not run simulations using administrative privileges.
set_origin{ }¶
- Calling sequence
output{ set_origin{ } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
items: \(\mathrm{maximum\;1}\)
- Functionality
Defines origin of coordinate system of the output files within the coordinate system of the simulation. If the origin of the output coordinate system is set to \(r_{\mathrm{ori}}\), then every vector in the simulation coordinate system \(r_{\mathrm{sim}}\) is transformed to
\[r_{\mathrm{out}} = r_{\mathrm{sim}} - r_{\mathrm{ori}}\]for every output file with results dependent on position.
set_origin{ x }¶
- Calling sequence
output{ set_origin{ x } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{real\;number}\)
values: no constraints
unit: \(\mathrm{nm}\)
default:
0
- Functionality
Defines x-coordinate of the origin of the output coordinate system \(r_{\mathrm{ori}}\) within the coordinate system of the simulation.
set_origin{ y }¶
- Calling sequence
output{ set_origin{ y } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{real\;number}\)
values: no constraints
unit: \(\mathrm{nm}\)
default:
0
- Functionality
Defines y-coordinate of the origin of the output coordinate system \(r_{\mathrm{ori}}\) within the coordinate system of the simulation.
set_origin{ z }¶
- Calling sequence
output{ set_origin{ z } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{real\;number}\)
values: no constraints
unit: \(\mathrm{nm}\)
default:
0
- Functionality
Defines z-coordinate of the origin of the output coordinate system \(r_{\mathrm{ori}}\) within the coordinate system of the simulation.
format2D¶
- Calling sequence
output{ format2D }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{choice}\)
choices:
yes
;no
values:
AvsBinary
;AvsAscii
;AvsBinary\_one\_file
;AvsAscii\_one\_file
;VtkAscii
;VtkAscii\_AvsAscii
;VtkAscii\_AvsAscii\_one\_file
;VtkAscii\_AvsBinary
;VtkAscii\_AvsBinary\_one\_file
;Origin
default:
AvsBinary_one_file
- Functionality
Sets format of output files with data defined on 2-dimensional spaces of any kind.
Note
Instead of
Vtk
one can writeVTK
. Likewise,Avs
can be replaced byAVS
.¶ Chosen option
Format
AvsBinary
…AVS/Express file format (AVS steering files
*.v
, and*.fld
,*.coord
,*.dat
data files) - data files in binary formatAvsAscii
…AVS/Express file format (AVS steering files
*.v
, and*.fld
,*.coord
,*.dat
data files) - data files in ASCII formatAvsBinary_one_file
…AVS/Express file format - header (ASCII), coordinates and variables (both binary) are written into a single
.fld
fileAvsAscii_one_file
…AVS/Express file format - header (ASCII), coordinates and variables (both ASCII) are written into a single
.fld
fileVTKAscii
…VTK XML ASCII format (
.vtr
,r
= rectilinear grid)VTKAscii_AvsAscii
…VTKAscii
+AvsAscii
VTKAscii_AvsAscii_one_file
…VTKAscii
+AvsAscii_one_file
VTKAscii_AvsBinary
…VTKAscii
+AvsBinary
VTKAscii_AvsBinary_one_file
…VTKAscii
+AvsBinary_one_file
Origin
Origin file format (Origin steering files
*.plt
, data files*.dat
)
format3D¶
- Calling sequence
output{ format3D }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{choice}\)
choices:
yes
;no
values:
AvsBinary
;AvsAscii
;AvsBinary\_one\_file
;AvsAscii\_one\_file
;VtkAscii
;VtkAscii\_AvsAscii
;VtkAscii\_AvsAscii\_one\_file
;VtkAscii\_AvsBinary
;VtkAscii\_AvsBinary\_one\_file
;Origin
default:
AvsBinary_one_file
- Functionality
Sets format of output files with data defined on 3-dimensional spaces of any kind.
Note
Instead of
Vtk
one can writeVTK
. Likewise,Avs
can be replaced byAVS
.¶ Chosen option
Format
AvsBinary
…AVS/Express file format (AVS steering files
*.v
, and*.fld
,*.coord
,*.dat
data files) - data files in binary formatAvsAscii
…AVS/Express file format (AVS steering files
*.v
, and*.fld
,*.coord
,*.dat
data files) - data files in ASCII formatAvsBinary_one_file
…AVS/Express file format - header (ASCII), coordinates and variables (both binary) are written into a single
.fld
fileAvsAscii_one_file
…AVS/Express file format - header (ASCII), coordinates and variables (both ASCII) are written into a single
.fld
fileVTKAscii
…VTK XML ASCII format (
.vtr
,r
= rectilinear grid)VTKAscii_AvsAscii
…VTKAscii
+AvsAscii
VTKAscii_AvsAscii_one_file
…VTKAscii
+AvsAscii_one_file
VTKAscii_AvsBinary
…VTKAscii
+AvsBinary
VTKAscii_AvsBinary_one_file
…VTKAscii
+AvsBinary_one_file
Origin
Origin file format (Origin steering files
*.plt
, data files*.dat
)
silent¶
- Calling sequence
output{ silent }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{choice}\)
choices:
yes
;no
default:
yes
- Functionality
If set to
no
then prints additional warnings concerning output.
write_avs_v¶
- Calling sequence
output{ write_avs_v }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{choice}\)
choices:
yes
;no
default:
no
- Functionality
Outputs AVS steering file
.v
.
write_origin_plt¶
- Calling sequence
output{ write_origin_plt }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{choice}\)
choices:
yes
;no
default:
no
- Functionality
Outputs Origin steering file
.plt
.
write_gnuplot_plt¶
- Calling sequence
output{ write_gnuplot_plt }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{choice}\)
choices:
yes
;no
default:
no
- Functionality
Outputs gnuplot file
.plt
.Attention
Currently, gnuplot format is only implemented for energy resolved densities in 1D, energy resolved photo generation in 1D, and light field and may generate huge files.
use_gnuplot_one_file¶
- Calling sequence
output{ use_gnuplot_one_file }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{choice}\)
choices:
yes
;no
default:
no
- Functionality
If
yes
then all information (metadata and data) necessary for the gnuplot figure is contained in one file.
only_sections¶
- Calling sequence
output{ only_sections }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{choice}\)
choices:
yes
;no
default:
no
If
only_sections = yes
then outputs only sections of 2D and 3D fields defined by output{ } will be generated. Thus, if no sections are defined then also no fields will be outputted. These files can be used to restrict field output to the actual regions of interest, or also to suppress most file I/O (if no sections are defined).Note
Quantities living on, e.g., an energy grid, integrative quantities like I-V curves, or files needed for resuming operation are not influenced by this setting.
Attention
This setting has no effect on RAM usage or on the fields used in the calculation, it just affects what is written into output files.
section{ }¶
- Calling sequence
output{ section{ } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
items: \(\mathrm{no\;constraints}\)
- Functionality
Generates outputs from selected range of the simulation domain. The range is defined by section{ range_x }, section{ range_y }, and section{ range_z }.
Attention
All section commands are ignored for energy resolved densities, energy resolved photo generation, and light field.
- Examples
output{ section{ name = "part" # name of section enters file name range_x = [0, 20] # range in x direction [nm] range_y = [-5, 5] # range in y direction [nm] (2D or 3D only) range_z = [2, 10] # range in z direction [nm] (3D only) } }
output{ directory = "../output/mosfet_2D" section{ name = "zoom" range_x = [0,20] # range in x direction from 0 nm to 20 nm range_y = [-5,5] # range in y direction from -5 nm to 5 nm } }
section{ name }¶
- Calling sequence
output{ section{ name } }
- Properties
usage: \(\mathrm{\textcolor{WildStrawberry}{required\;within\;the\;group}}\)
type: \(\mathrm{character\;string}\)
- Functionality
Defines a suffix to a name of the generated output file.
section{ range_x }¶
- Calling sequence
output{ section{ range_x } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{vector\;of\;2\;real\;numbers}\)
values: no constraints
default:
[0.0, 0.0]
unit: \(\mathrm{nm}\)
- Functionality
Defines a range interval along the x-direction of the simulation domain for the additional output. The first number defines the beginning of the interval and the second defines its end.
Note
Ranges in sections must contain at least one grid point. If no point is found inside the range then the closest grid point is used. Zero-length intervals, such as
[50.1, 50.1]
, are allowed.
section{ range_y }¶
- Calling sequence
output{ section{ range_y } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{vector\;of\;2\;real\;numbers}\)
values: no constraints
default:
[0.0, 0.0]
unit: \(\mathrm{nm}\)
- Functionality
Defines a range interval along the y-direction of the simulation domain for the additional output. The first number defines the beginning of the interval and the second defines its end.
Note
Ranges in sections must contain at least one grid point. If no point is found inside the range then the closest grid point is used. Zero-length intervals, such as
[50.1, 50.1]
, are allowed.
section{ range_z }¶
- Calling sequence
output{ section{ range_z } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{vector\;of\;2\;real\;numbers}\)
values: no constraints
default:
[0.0, 0.0]
unit: \(\mathrm{nm}\)
- Functionality
Defines a range interval along the z-direction of the simulation domain for the additional output. The first number defines the beginning of the interval and the second defines its end.
Note
Ranges in sections must contain at least one grid point. If no point is found inside the range then the closest grid point is used. Zero-length intervals, such as
[50.1, 50.1]
, are allowed.
section1D{ }¶
- Calling sequence
output{ section1D{ } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
items: \(\mathrm{no\;constraints}\)
- Functionality
Outputs a 1D section of the simulation area, a 1D slice, from 2D or 3D simulation.
Note
- 2D usage:
x
,range_y
| 1D slice atx
= … nm within the range fromy
= … nm toy
= … nm ory
,range_x
| 1D slice aty
= … nm within the range fromx
= … nm tox
= … nm
- 3D usage:
x
,y
,range_z
or | 1D slice atx
= … nm andy
= … nm within the range fromz
= … nm toz
= … nm | …
If range is left out, the section extends over the whole simulation area.
- Examples
output{ section1D{ name = "x" # name of section enters file name x = 10.0 # 1D slice at x = 10 nm y = 10.0 # 1D slice at y = 10 nm z = 10.0 # 1D slice at z = 10 nm (3D only) range_x = [0, 20] # (optional) range in x direction [nm] range_y = [-5, 5] # (optional) range in y direction [nm] range_z = [2, 10] # (optional) range in z direction [nm] (3D only) } }
output{ directory = "../output/mosfet_3D" section1D{ name = "x" y = 10 z = 10 } }
output{ directory = "../output/mosfet_2D" section1D{ name = "y" y = 10 # 1D slice at y = 10 nm range_x = [-20, 220.5] # range in x direction from -20 nm to 220.5 nm } }
section1D{ name }¶
- Calling sequence
output{ section1D{ name } }
- Properties
usage: \(\mathrm{\textcolor{WildStrawberry}{required\;within\;the\;group}}\)
type: \(\mathrm{character\;string}\)
- Functionality
Defines a suffix to a name of the generated output file.
section1D{ x }¶
- Calling sequence
output{ section1D{ x } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{real\;number}\)
values: no constraints
default:
0.0
unit: \(\mathrm{nm}\)
- Functionality
Defines position along the x-direction of the simulation domain at which the section of generated data is created and added to the output.
section1D{ y }¶
- Calling sequence
output{ section1D{ y } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{real\;number}\)
values: no constraints
default:
0.0
unit: \(\mathrm{nm}\)
- Functionality
Defines position along the y-direction of the simulation domain at which the section of generated data is created and added to the output.
section1D{ z }¶
- Calling sequence
output{ section1D{ z } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{real\;number}\)
values: no constraints
default:
0.0
unit: \(\mathrm{nm}\)
- Functionality
Defines position along the z-direction of the simulation domain at which the section of generated data is created and added to the output.
section1D{ range_x }¶
- Calling sequence
output{ section1D{ range_x } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{vector\;of\;2\;real\;numbers}\)
values: no constraints
default:
[0.0, 0.0]
unit: \(\mathrm{nm}\)
- Functionality
Defines a range interval along the x-direction of the simulation domain for the additional output. The first number defines the beginning of the interval and the second defines its end.
Note
Ranges in sections must contain at least one grid point. If no point is found inside the range then the closest grid point is used. Zero-length intervals, such as
[50.1, 50.1]
, are allowed.
section1D{ range_y }¶
- Calling sequence
output{ section1D{ range_y } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{vector\;of\;2\;real\;numbers}\)
values: no constraints
default:
[0.0, 0.0]
unit: \(\mathrm{nm}\)
- Functionality
Defines a range interval along the y-direction of the simulation domain for the additional output. The first number defines the beginning of the interval and the second defines its end.
Note
Ranges in sections must contain at least one grid point. If no point is found inside the range then the closest grid point is used. Zero-length intervals, such as
[50.1, 50.1]
, are allowed.
section1D{ range_z }¶
- Calling sequence
output{ section1D{ range_z } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{vector\;of\;2\;real\;numbers}\)
values: no constraints
default:
[0.0, 0.0]
unit: \(\mathrm{nm}\)
- Functionality
Defines a range interval along the z-direction of the simulation domain for the additional output. The first number defines the beginning of the interval and the second defines its end.
Note
Ranges in sections must contain at least one grid point. If no point is found inside the range then the closest grid point is used. Zero-length intervals, such as
[50.1, 50.1]
, are allowed.
section2D{ }¶
- Calling sequence
output{ section2D{ } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
items: \(\mathrm{no\;constraints}\)
- Functionality
Outputs a 2D section of the simulation area, a 2D slice, from 3D simulation.
Note
- 3D usage:
x
,range_y
,range_z
| 2D slice atx
= … nm within the range fromy
= … nm toy
= … nm and fromz
= … nm toz
= … nm ory
,range_x
,range_z
| 2D slice aty
= … nm within the range fromx
= … nm tox
= … nm and fromz
= … nm toz
= … nm orz
,range_x
,range_y
| 2D slice atz
= … nm within the range fromx
= … nm tox
= … nm and fromy
= … nm toy
= … nm
- Examples
output{ section2D{ name = "center" # name of section enters file name x = 10.0 # 2D slice at x = 10 nm y = 20.0 # 2D slice at y = 20 nm z = 10.0 # 2D slice at z = 10 nm range_x = [0, 20] # (optional) range in x direction [nm] range_y = [-5, 5] # (optional) range in y direction [nm] range_z = [2, 10] # (optional) range in z direction [nm] } }
output{ directory = "../output/mosfet_3D" section2D{ name = "y" y = 10 # 2D slice at y = 10 nm range_x = [-20, 220.5] # range in x direction from -20 nm to 220.5 nm range_z = [-20, 220.5] # range in z direction from -20 nm to 220.5 nm } }
material_parameters{ }¶
- Calling sequence
output{ material_parameters{ } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
items: \(\mathrm{maximum\;1}\)
- Functionality
Defines additional outputs.
material_parameters{ kp_parameters{ } }¶
- Calling sequence
output{ material_parameters{ kp_parameters{ } } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
items: \(\mathrm{maximum\;1}\)
- Functionality
- Outputs
\(\mathbf{k} \cdot \mathbf{p}\) parameters of materials in quantum regions where 6-band or 8-band \(\mathbf{k} \cdot \mathbf{p}\) Hamiltonian was solved,
the Dresselhaus-Kip-Kittel (DKK) parameters (
L
,M
,N
), which are used internally in the code,the Luttinger parameters (
gamma1
,gamma2
,gamma3
,kappa
) (for zinc blende) or Rashba-Sheka-Pikus (A1
,A2
, …,A6
) parameters (for wurtzite),the
S
,E_P
,P
andB
parameters for 8-band \(\mathbf{k} \cdot \mathbf{p}\) calculations.
For further information, consult Chapter 3 of [BirnerPhD2011].
material_parameters{ kp_parameters{ boxes } }¶
- Calling sequence
output{ material_parameters{ kp_parameters{ boxes } } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{choice}\)
choices:
yes
;no
default:
no
- Functionality
For each grid point, in 1D two points are printed out to mimic abrupt discontinuities at interfaces (in 2D four points, in 3D eight points)
material_parameters{ spin_orbit_coupling_energies{ } }¶
- Calling sequence
output{ material_parameters{ spin_orbit_coupling_energies{ } } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
items: \(\mathrm{maximum\;1}\)
- Functionality
Outputs spin-orbit coupling energy for zinc blende (1 parameter) or crystal-field splitting and spin-orbit coupling energies for wurtzite (3 parameters) in
[eV]
.
material_parameters{ spin_orbit_coupling_energies{ boxes } }¶
- Calling sequence
output{ material_parameters{ spin_orbit_coupling_energies{ boxes } } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{choice}\)
choices:
yes
;no
default:
no
- Functionality
For each grid point, in 1D two points are printed out to mimic abrupt discontinuities at interfaces (in 2D four points, in 3D eight points)
material_parameters{ charge_carrier_masses{ } }¶
- Calling sequence
output{ material_parameters{ charge_carrier_masses{ } } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
items: \(\mathrm{maximum\;1}\)
- Functionality
Outputs effective masses of all energy bands used in the simulations in
[m0]
.
material_parameters{ charge_carrier_masses{ boxes } }¶
- Calling sequence
output{ material_parameters{ charge_carrier_masses{ boxes } } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{choice}\)
choices:
yes
;no
default:
no
- Functionality
For each grid point, in 1D two points are printed out to mimic abrupt discontinuities at interfaces (in 2D four points, in 3D eight points)
material_parameters{ static_dielectric_constants{ } }¶
- Calling sequence
output{ material_parameters{ static_dielectric_constants{ } } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
items: \(\mathrm{maximum\;1}\)
- Functionality
Outputs static relative dielectric constants for zinc blende (1 parameter) and wurtzite (3 parameters).
material_parameters{ static_dielectric_constants{ boxes } }¶
- Calling sequence
output{ material_parameters{ static_dielectric_constants{ boxes } } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{choice}\)
choices:
yes
;no
default:
no
- Functionality
For each grid point, in 1D two points are printed out to mimic abrupt discontinuities at interfaces (in 2D four points, in 3D eight points)
material_parameters{ deformation_potentials{ } }¶
- Calling sequence
output{ material_parameters{ deformation_potentials{ } } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
items: \(\mathrm{maximum\;1}\)
- Functionality
Output the deformation potentials for zinc blende and wurtzite in
[eV]
.
material_parameters{ deformation_potentials{ boxes } }¶
- Calling sequence
output{ material_parameters{ deformation_potentials{ boxes } } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{choice}\)
choices:
yes
;no
default:
no
- Functionality
For each grid point, in 1D two points are printed out to mimic abrupt discontinuities at interfaces (in 2D four points, in 3D eight points)