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For the best results it is recommended to use NETCDF output on the icosahedral grid which ICON-ART is using. However in some applications remapping the grid to a latitude-longitude grid may be required, which can be set via the <code>remap</code> option. A corresponding output namelist for sea salt on model levels can be seen here:
For the best results it is recommended to use NETCDF output on the icosahedral grid which ICON-ART is using. However in some applications remapping the grid to a latitude-longitude grid may be required, which can be set via the <code>remap</code> option. A corresponding output namelist for sea salt on model levels can be seen here:


<syntaxhighlight lang=bash line>
<pre>NAMELIST EXAMPLE
NAMELIST EXAMPLE
&amp;output_nml
&amp;output_nml
filetype = 4 ! output format: 2=GRIB2, 4=NETCDFv2
filetype = 4 ! output format: 2=GRIB2, 4=NETCDFv2
dom = 1 ! write output for domain 1
dom = 1 ! write output for domain 1
output_start = &quot;JJJJ-MM-DDTHH:MM:SSZ&quot; !put date in
output_start = 'JJJJ-MM-DDTHH:MM:SSZ' !put date in
output_end = &quot;JJJJ-MM-DDTHH:MM:SSZ&quot; !put date in
output_end = 'JJJJ-MM-DDTHH:MM:SSZ' !put date in
output_interval = &quot;PT1H&quot; ! \href{ISO8601}{https://en.wikipedia.org/wiki/ISO_8601}
output_interval = 'PT1H' ! see https://en.wikipedia.org/wiki/ISO_8601
steps_per_file = 1 ! max. num. of time steps within one file
steps_per_file = 1 ! max. num. of time steps within one file
mode = 1 ! 1: forecast mode (relative t-axis)
mode = 1 ! 1: forecast mode (relative t-axis)
include_last = .TRUE. ! include the last time step
include_last = .TRUE. ! include the last time step
output_filename = '&lt;INSERTFILENAME&gt;' ! file name base
output_filename = 'INSERTFILENAME' ! file name base
ml_varlist = 'seasa','seasb','seasc',
ml_varlist = 'seasa','seasb','seasc',
'seasa0','seasb0','seasc0'
'seasa0','seasb0','seasc0'
remap = 1 ! output is transferred to lat long grid
remap = 1 ! output is transferred to lat long grid
reg_lon_def = -180.,0.5,179.5 !start, incr., end, in deg.
reg_lon_def = -180.,0.5,179.5 !start, incr., end, in deg.
reg_lat_def = 90.,-0.5, -90. !start, incr., end, in deg.</pre>
reg_lat_def = 90.,-0.5, -90. !start, incr., end, in deg.
</syntaxhighlight>




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To include a group of Variables in the output file change the namelist variable ml_varlist from the example above to the following:
To include a group of Variables in the output file change the namelist variable ml_varlist from the example above to the following:


<pre>ml_varlist = 'group:ART_DIAGNOSTICS'</pre>
<pre>ml_varlist = 'group:ART_AEROSOL'</pre>
The output variables that are associated to this group will be written to the output file. You can check the groups of output variables in this [[#OutputTable | Table]] .
The output variables that are associated to this group will be written to the output file. You can check the groups of output variables in this [[#OutputTable | Table]] .


== Aerosol Naming Conventions ==
== Finding the correct Mode description ==
The following table contains an overview of the possible output variables.
The following table contains an overview of the possible output variables.


There are several ways to choose the Naming of the output variables, depending on your application
Currently there are two ways to specify Tracer in ICON-ART: The classical way and via AERODYN:


* '''Classical:''' : The Tracers for Dust, Seasalt, Ash and Soot are combined with the three Possible modes a, b and c, which correspond to the different size bins of the particles.
* '''Externally mixed Aerosols:''' : The Tracers for Dust, Seasalt, Ash and Soot are combined with the three Possible modes a, b and c, which correspond to the different size bins of the particles <div id="OutputTable"></div>


::{| class="wikitable" style="text-align:left;"
<div id="OutputTable"></div>
|+ Externally mixed Tracer modes
{| class="wikitable" style="text-align:left;"
|+ Classical Tracer configurations
!|| dust||seasalt ||ash ||soot
!|| dust||seasalt ||ash ||soot
|-
|-
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|-
|-
!b
!b
| dustb ||seasb ||ashb ||sootb
| dustb ||seasb ||ashb ||-
|-
|-
!c
!c
| dustc||seasc ||ashc ||sootc
| dustc||seasc ||ashc ||-
|-
|-
|}
|}
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* '''Using AERODYN:''' Here a tracer is defined in a different way, with the goal being to have a more flexible framework for various applications. In this framework modes are created in a different way, as illustrated int the table below:
* '''Internally mixed Aerosols ([[AERODYN]]):''' Here a tracer is defined in a different way, with the goal being to have a more flexible framework for various applications. In this framework modes are created in a different way, as illustrated int the table below:


<div id="OutputTable"></div>
<div id="OutputTable"></div>
{| class="wikitable" style="text-align:left;"
::{| class="wikitable" style="text-align:left;"
|+ AERODYN mode configurations
|+ AERODYN mode configurations
! || aitken || accumulation || coarse || giant
! || aitken || accumulation || coarse || giant
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The modes are then combined with The Tracername to obtain the name of the Variable using <code>varname = 'Tracer' + '_' + 'mode from Table'</code>.
The modes are then combined with The Tracername to obtain the name of the Variable using <code>varname = 'Tracer' + '_' + 'mode from Table'</code>.
Example : <code> dust_insol_acc </code>
Example : <code> dust_insol_acc </code>

* '''Monodisperse Aerosols'''


== Available Output Variables ==
== Available Output Variables ==

Latest revision as of 09:15, 7 September 2023


General Remarks

In principle, output of ICON-ART variables works the same way as for ICON variables. As described in , the following five quantities of the output have to be specified:

  • The time interval between two model outputs.
  • The name of the output file.
  • The name of the variable(s) and/or variable group(s).
  • The type of vertical output grid.
  • The type of horizontal output grid.

For the best results it is recommended to use NETCDF output on the icosahedral grid which ICON-ART is using. However in some applications remapping the grid to a latitude-longitude grid may be required, which can be set via the remap option. A corresponding output namelist for sea salt on model levels can be seen here:

NAMELIST EXAMPLE
&amp;output_nml
 filetype            =  4     ! output format: 2=GRIB2, 4=NETCDFv2
 dom                 =  1     ! write output for domain 1
 output_start        =  'JJJJ-MM-DDTHH:MM:SSZ' !put date in
 output_end          =  'JJJJ-MM-DDTHH:MM:SSZ' !put date in
 output_interval     =   'PT1H'  ! see https://en.wikipedia.org/wiki/ISO_8601  
 steps_per_file      =  1     ! max. num. of time steps within one file
 mode                =  1     ! 1: forecast mode (relative t-axis)
 include_last        = .TRUE. ! include the last time step
 output_filename     = 'INSERTFILENAME' ! file name base
 ml_varlist          = 'seasa','seasb','seasc',
 'seasa0','seasb0','seasc0'
 remap               = 1      ! output is transferred to lat long grid
 reg_lon_def         = -180.,0.5,179.5   !start, incr., end, in deg.
 reg_lat_def         = 90.,-0.5, -90. !start, incr., end, in deg.


There is an option to obtain all diagnostic Variables of a certain Group without having to specifying all of them. For example, you may use the group ART_DIAGNOSTICS.

To include a group of Variables in the output file change the namelist variable ml_varlist from the example above to the following:

ml_varlist          = 'group:ART_AEROSOL'

The output variables that are associated to this group will be written to the output file. You can check the groups of output variables in this Table .

Aerosol Naming Conventions

The following table contains an overview of the possible output variables.

There are several ways to choose the Naming of the output variables, depending on your application

  • Externally mixed Aerosols: : The Tracers for Dust, Seasalt, Ash and Soot are combined with the three Possible modes a, b and c, which correspond to the different size bins of the particles
Externally mixed Tracer modes
dust seasalt ash soot
a dusta seasa asha soota
b dustb seasb ashb -
c dustc seasc ashc -


  • Internally mixed Aerosols (AERODYN): Here a tracer is defined in a different way, with the goal being to have a more flexible framework for various applications. In this framework modes are created in a different way, as illustrated int the table below:
AERODYN mode configurations
aitken accumulation coarse giant
soluble sol_aitken sol_acc sol_coarse sol_giant
insoluble insol_aitken insol_acc insol_coarse insol_giant
mixed mixed_aitken mixed_acc mixed_coarse mixed_giant

The modes are then combined with The Tracername to obtain the name of the Variable using varname = 'Tracer' + '_' + 'mode from Table'. Example : dust_insol_acc

  • Monodisperse Aerosols

Available Output Variables

The following Table contains an overview over the diagnostic Icon-ART Variables. Expressions in Brackets are Placeholders which can be used to construct the name of the actual variables:

[aeronet wavelength] => [340, 380, 440, 500, 550, 675, 870, 1020, 1064]

[ceilo_wavelength] => [355,532,1064]

[pollen] => [ALNU,BETU,...] to be defined in diagnostics.xml



Output Overview
varname groups unit descripition namelist switch required xml
Aerosols diam_[mode] ART_DIAGNOSTICS m with AERODYN : aerosol diameter lart_aerosol=True and lart_diag_out=True requires cart_diagnostics_xml file
diam_[aerosol][mode] ART_DIAGNOSTICS m WITHOUT AERODYN: aerosol diameter lart_aerosol=True and lart_diag_out=True requires cart_diagnostics_xml file
aod_[aerosol]_[aeronet wavelength]nm ART_DIAGNOSTICS , ART_ROUTINE_DIAG Layer-1 [AEROSOL] optical depth lart_aerosol=True and lart_diag_out=True requires cart_diagnostics_xml file
bsc_[arosol]_[ceilo_wavelength]nm ART_DIAGNOSTICS m-1 sr-1 [AEROSOL] backscatter lart_aerosol=True and lart_diag_out=True requires cart_diagnostics_xml file
ceil_[arosol]_[ceilo_wavelength]nm ART_DIAGNOSTICS , ART_ROUTINE_DIAG m-1 sr-1 [AEROSOL] Attenuated Backscatter Ceilometer lart_aerosol=True and lart_diag_out=True requires cart_diagnostics_xml file
sat_[arosol]_[ceilo_wavelength]nm ART_DIAGNOSTICS m-1 sr-1 [AEROSOL] Attenuated Backscatter Satellite lart_aerosol=True and lart_diag_out=True requires cart_diagnostics_xml file
AOD_550_so4_sol ART_DIAGNOSTICS layer-1 SO4 sol Optical Depth lart_aerosol=True and lart_diag_out=True requires cart_diagnostics_xml file
AOD_550_ash_insol ART_DIAGNOSTICS layer-1 Ash insol Optical Depth lart_aerosol=True and lart_diag_out=True requires cart_diagnostics_xml file
AOD_550_ash_mixed ART_DIAGNOSTICS layer-1 Ash mixed Optical Depth lart_aerosol=True and lart_diag_out=True requires cart_diagnostics_xml file
AOD_550_ash_giant ART_DIAGNOSTICS layer-1 Ash giant Optical Depth lart_aerosol=True and lart_diag_out=True requires cart_diagnostics_xml file
ustar_thres ART_ROUTINE_DIAG m s-1 threshold friction velocity for dust emission' lart_aerosol=True and lart_diag_out=True requires cart_diagnostics_xml file
ustar ART_ROUTINE_DIAG m s-1 Friction velocity lart_aerosol=True and lart_diag_out=True requires cart_diagnostics_xml file
acc_drydepo_[tracer] ART_DIAGNOSTICS , ART_ROUTINE_DIAG tracer-unit m-2 accumulated dry deposition of tracer lart_aerosol=True and lart_diag_out=True requires cart_diagnostics_xml file
acc_sedim_[tracer] ART_DIAGNOSTICS , ART_ROUTINE_DIAG tracer-unit m-2 accumulated sedimentation of tracer lart_aerosol=True and lart_diag_out=True requires cart_diagnostics_xml file
acc_wetdepo_gscp_[tracer] ART_DIAGNOSTICS , ART_ROUTINE_DIAG tracer-unit m-2 accumulated wet deposition by grid scale precipitation of tracer lart_aerosol=True and lart_diag_out=True requires cart_diagnostics_xml file
acc_wetdepo_con_[tracer] ART_DIAGNOSTICS , ART_ROUTINE_DIAG tracer-unit m-2 accumulated wet deposition by convective precipitation of tracer lart_aerosol=True and lart_diag_out=True requires cart_diagnostics_xml file
acc_wetdepo_rrsfc_[tracer] ART_DIAGNOSTICS , ART_ROUTINE_DIAG tracer-unit m-2 accumulated wet deposition of tracer if precipitation reaches surface lart_aerosol=True and lart_diag_out=True requires cart_diagnostics_xml file
emiss_[tracer] ART_DIAGNOSTICS , ART_ROUTINE_DIAG tracer-unit m-2 s-1 emission of tracer lart_aerosol=True and lart_diag_out=True requires cart_diagnostics_xml file
acc_emiss_[tracer] ART_DIAGNOSTICS , ART_ROUTINE_DIAG tracer-unit m-2 accumulated emission of tracer lart_aerosol=True and lart_diag_out=True requires cart_diagnostics_xml file
Pollen [pollen]rprec ART_ROUTINE_DIAG m-2 precipitation reservoir of [pollen] iart_pollen>0 REQUIRES diagnostics.xml
[pollen]reso ART_ROUTINE_DIAG m-2 Pollen reservoir (previous timestep) of [pollen] iart_pollen>0 REQUIRES diagnostics.xml
[pollen]ress ART_ROUTINE_DIAG m-2 Pollen reservoir (daily sum) of [pollen] iart_pollen>0 REQUIRES diagnostics.xml
[pollen]sdes ART_ROUTINE_DIAG - State of pollen season of [pollen] iart_pollen>0 REQUIRES diagnostics.xml
[pollen]ctsum ART_ROUTINE_DIAG K Cumulated weighted 2m temperature sum of [pollen] iart_pollen>0 REQUIRES diagnostics.xml
[pollen]saisn ART_ROUTINE_DIAG days Number of days since start of pollen season of [pollen] iart_pollen>0 REQUIRES diagnostics.xml
[pollen]saisl ART_ROUTINE_DIAG days length of pollen season of [pollen] iart_pollen>0 REQUIRES diagnostics.xml
[pollen]saisa ART_ROUTINE_DIAG days Number of days since the start of pollen season of [pollen]. if present day is out of the season: length of current season REQUIRES diagnostics.xml
[pollen]fe ART_ROUTINE_DIAG m-2 s-1 Emission flux of [pollen] iart_pollen>0 REQUIRES diagnostics.xml
Chemistry reac_rates ART_DIAGNOSTICS s-1 MECCA reaction rates lart_mecca=True, lart_diag_out=True
art_o3 kg/kg Ozone mass mixing ratio lart_chem =True, lart_diag_out=True
OH_Nconc # / cm3 OH number concentration lart_chem =TRUE
photo - s-1 photolysis rates lart_chem=TRUE, lart_mecca=TRUE
art_full_chemistry_o3_col - DU Ozone column lart_chem=TRUE, lart_mecca=TRUE
sts_liqsur ART_DIAGNOSTICS cm2 cm-3 liquid area density of STS lart_chem=TRUE , lart_psc=TRUE
cgaml ART_DIAGNOSTICS - STS uptake coefficient of the reaction lart_chem=TRUE , lart_psc=TRUE
dens_ice ART_DIAGNOSTICS m-3 number density of ice particles lart_chem=TRUE , lart_psc=TRUE
radius_ice ART_DIAGNOSTICS m radius of ice particles lart_chem=TRUE , lart_psc=TRUE
radius_STS ART_DIAGNOSTICS m radius of STS particles lart_chem=TRUE , lart_psc=TRUE
dens_NAT ART_DIAGNOSTICS m-3 number density of NAT particles lart_chem=TRUE , lart_psc=TRUE
radius_NAT ART_DIAGNOSTICS m radius of NAT particles lart_chem=TRUE , lart_psc=TRUE
HNO3_Nconc_s ART_DIAGNOSTICS cm-3 number concentration of HNO3 in NAT lart_chem=TRUE , lart_psc=TRUE
HNO3_Nconc_l ART_DIAGNOSTICS cm-3 number concentration of HNO3 in STS lart_chem=TRUE , lart_psc=TRUE
ice_vmr_Marti ART_DIAGNOSTICS mol mol-1 volume mixing ratio of solid water by Marti and Mauersberger lart_chem=TRUE , lart_psc=TRUE
NAT_sedi_rel_difference ART_DIAGNOSTICS - relative difference of NAT mass bef and aft sedi (aft - bef) * 2 / (aft + bef) lart_chem=TRUE , lart_psc=TRUE
NAT_sedi_vel ART_DIAGNOSTICS m s-1 sedimentation velocity of NAT particles lart_chem=TRUE , lart_psc=TRUE
art_so2_col ART_DIAGNOSTICS DU SO2 column lat_chem=TRUE , lart_chemtracer=TRUE
Radioactive Tracer Diagnostics wet deposition of xml defined tracer ART_DIAGNOSTICS, ART_ROUTINE_DIAG Bq m-2 wet deposition of xml defined tracer lart_aerosol=True and iart_radioact=1
dry deposition of xml defined tracer ART_DIAGNOSTICS, ART_ROUTINE_DIAG Bq m-2 dry deposition of xml defined tracer lart_aerosol=True and iart_radioact=1
Averaged air concentration of xml defined traer ART_DIAGNOSTICS, ART_ROUTINE_DIAG Bq m-3 Averaged air concentration of xml defined traer lart_aerosol=True and iart_radioact=1
FPLUME Output plume_height ART_FPLUME m plume height iart_fplume/=0
plume_MFR ART_FPLUME kg s-1 plume MFR iart_fplume/=0
MER_transport ART_FPLUME kg s-1 Amount of very fine ash for transport iart_fplume/=0
solution_with ART_FPLUME - FPlume off, Mastin, or FPlume iart_fplume/=0