Difference between revisions of "UKCA & UMUI Tutorial 6"
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'<span style="color:purple">Product 4 </span>', <span style="color:blue">Fraction of Product 1 produced</span>, <span style="color:red">Fraction of Product 2 produced</span>, <span style="color:green">Fraction of Product 3 produced</span>, <span style="color:purple">Fraction of Product 4 produced</span>, Quantum Yield, Look-up Label), & |
'<span style="color:purple">Product 4 </span>', <span style="color:blue">Fraction of Product 1 produced</span>, <span style="color:red">Fraction of Product 2 produced</span>, <span style="color:green">Fraction of Product 3 produced</span>, <span style="color:purple">Fraction of Product 4 produced</span>, Quantum Yield, Look-up Label), & |
||
− | The '''Look-Up Label''' is used to define the file used for the 2D |
+ | The '''Look-Up Label''' is used to define the file used for the 2D photolysis, and is used by Fast-J/Fast-JX to find the correct values for each species in the input data files. Examples of this type are |
ratj_t('H2O2 ','PHOTON ','OH ','OH ',' ', & |
ratj_t('H2O2 ','PHOTON ','OH ','OH ',' ', & |
Revision as of 15:12, 21 June 2013
Adding new Chemical Reactions
UKCA currently uses two different methods of defining the chemical reactions solved in the model. The first is a backward Euler solver, and is used for the RAQ and StdTrop chemistry schemes where the solver itself is created by a code-writer. The second makes use of the ASAD chemical integration software package, and is used for the CheT/TropIsop, CheS/Strat, and CheST/StratTrop chemistry schemes. ASAD can use many different solvers, although currently it uses symbolic Newton-Raphson solver. In this tutorial we will only consider the ASAD framework, as this is easily extended by a user.
ASAD considers four different types of chemical reactions: bimolecular reactions, termolecular reactions, heterogeneous reactions, and photolysis reactions.
Biomolecular Reactions
For most bimolecular reactions, it is sufficient to provide the , , and coefficients that are used to compute the rate coefficient from the Arrhenius expression
Chemistry Defition Routines
The bimolecular reactions are defined in the ukca_chem_scheme.F90 routines using the ratb_t Fortran type specification, and are held in arrays. At the end of this routine the ratb_defs_scheme array is created from these, and if that scheme is selected in UKCA these reactions are copied across into the master ratb_defs array.
To format of this ratb_t type is
ratb_t('Reactant 1','Reactant 2','Product 1 ','Product 2 ','Product 3 ',& 'Product 4 ', , , , Fraction of Product 1 produced, Fraction of Product 2 produced, Fraction of Product 3 produced, Fraction of Product 4 produced), &
Where the fraction of a product can be set to 0.000 if this functionality does not need to be used, i.e. the fraction is 1.0.
The specifications of the induvidual reactions are done as, e.g.
ratb_t('OH ','C5H8 ','ISO2 ',' ',' ',& ! B144 ' ', 2.70E-11, 0.00, -390.00, 0.000, 0.000, 0.000, 0.000), & ! B144 IUPAC2009 ... ratb_t('OH ','HCl ','H2O ','Cl ',' ',& ! B159 ' ', 1.80E-12, 0.00, 250.00, 0.000, 0.000, 0.000, 0.000), & ! B159 JPL2011
The first reaction in these examples takes its kinetic data from IUPAC. Going to this website, this reaction is defined here. The second reaction above takes its kinetic data from NASA's Jet Propulsion Laboritory. The rate for this can be found on page 1-19 of the JPL2011 document. When adding new reactions you will need to increment the size of the array holding the ratb_t type.
If there is a reaction that is an exception to the general Arrhenius equation then special code needs to be placed in the asad_bimol.F90 routine, which is held in the UKCA/ directory.
Increase the size of JPBK (and JPNR)
As well as adding these reactions to the ukca_chem_scheme.F90 routine (and incrementing the size of the arrays in that routine accordingly, you will also need to increase the values of two parameters that UKCA needs. These are
- JPBK is the number of bimolecular reactions
- JPNR is the total number of reactions
These are set automatically in the UMUI (depending on what scheme is chosen), and are placed in the &RUN_UKCA
namelist in CNTLATM. You will need to make a hand-edit to change these accordingly. The current values can be found by saving and processing the job, and then viewing the CNTLATM file in the $HOME/umui_jobs/jobid directory.
Termolecular Reactions
As well as defining reactions involving a third body, the termolecular rate definition can also be used to define unimolecular reactions.
The pressure and temperature dependent rate, , of a termolecular reaction is given by
where the low pressure rate constant is given by
and the high pressure rate constant is given by
Chemistry Defition Routines
The termolecular reactions are defined in the ukca_chem_scheme.F90 routines using the ratt_t Fortran type specification, and are held in one arrays (there are not usually enough reactions to require splitting the reactions over several arrays).
To format of this ratt_t type is
ratt_t('Reactant 1','Reactant 2','Product 1 ','Product 2 ', , & , , , , , , Fraction of Product 1 produced, Fraction of Product 2 produced), &
and as in ratb_t, where the fraction of a product can be set to 0.000 if this functionality does not need to be used, i.e. the fraction is 1.0.
The value is used to define the value by
If then
else
as the may or may not be highly temperature dependent.
Examples of these reactions are
ratt_t('N2O5 ','m ','NO2 ','NO3 ', 0.3, & ! T023 1.30E-03, -3.50, 11000.00, 9.70E+14, 0.10, 11080.00, 0.000, 0.000), & ! T023 IUPAC 2002 ratt_t('NO ','NO ','NO2 ','NO2 ', 0.0, & ! T024 3.30E-39, 0.00, -530.00, 0.00E+00, 0.00, 0.00, 0.000, 0.000) & ! T024 IUPAC 2001
When adding new reactions you will need to increment the size of the array holding the ratt_t type.
Increase the size of JPTK (and JPNR)
As with the bimolecular reactions, you will also need to increase the values of two parameters that UKCA needs. These are
- JPTK is the number of termolecular reactions
- JPNR is the total number of reactions
These are set automatically in the UMUI (depending on what scheme is chosen), and are placed in the &RUN_UKCA
namelist in CNTLATM. You will need to make a hand-edit to change these accordingly. The current values can be found by saving and processing the job, and then viewing the CNTLATM file in the $HOME/umui_jobs/jobid directory.
Heterogeneous Reactions
Heterogeneous reactions are those that occur on aerosol surfaces. There is no functional form defined for these reactions, with special code needed to be added for each case.
Chemistry Defition Routines
The heterogeneous reactions are defined in the ukca_chem_scheme.F90 routines using the rath_t Fortran type specification, usually in one array. To format of this rath_t type is
rath_t('Reactant 1','Reactant 2','Product 1 ','Product 2 ','Product 3 ',& 'Product 4 ', Fraction of Product 1 produced, Fraction of Product 2 produced, Fraction of Product 3 produced, Fraction of Product 4 produced), &
i.e. there is no rate information provided. For reactions on PSCs special code has been added to the routines in ukca_hetero_mod.F90, and for other reactions there is code in asad_hetero.F90. Examples of this type are
rath_t('ClONO2 ','H2O ','HOCl ','HONO2 ',' ', & ' ', 0.000, 0.000, 0.000, 0.000), & ... rath_t('SO2 ','H2O2 ','NULL0 ',' ',' ', & !HSO3+H2O2(aq) ' ', 0.000, 0.000, 0.000, 0.000), &
Increase the size of JPHK (and JPNR)
As with the bimolecular and termolecular reactions, you will also need to increase the values of two parameters that UKCA needs. These are
- JPHK is the number of heterogeneous reactions
- JPNR is the total number of reactions
These are set automatically in the UMUI (depending on what scheme is chosen), and are placed in the &RUN_UKCA
namelist in CNTLATM. You will need to make a hand-edit to change these accordingly. The current values can be found by saving and processing the job, and then viewing the CNTLATM file in the $HOME/umui_jobs/jobid directory.
Photolysis Reactions
These define a reaction where a chemical compound is broken down by photons. There is no functional form defined for this type of reaction. Instead, either in the troposphere input files are used to define the reaction rates for each species, in the stratosphere on-line look-up tables are generated for these rates (also for each species), or separate photolysis codes, Fast-J and Fast-JX, are used to interactively calculate the rate of reaction throughout the troposphere (for Fast-J) or the whole atmosphere (for Fast-JX). These interactive schemes are preferred as it takes the effect of aerosols or clouds into account at each timestep, allowing for more feedbacks to be investigated. In the upper stratosphere there are some wavelength regions that Fast-JX does not consider, and so the 3D on-line look-up tables are also used for these regions.
Tropospheric Off-Line Photolysis
If Fast-JX is not being used, then the off-line two-dimensional (zonally average) tropospheric photolysis is used (for all schemes). It is based on the work of Hough (1988)[1] and Law et al (1998)[2].
This scheme makes use of datafile which define the reaction rate for a particular species (e.g. H2O2), or if no rate is know, a nil rate can be used. For UM 8.2 these files (in ASCII format) can be found in
/work/n02/n02/hum/vn8.2/ctldata/UKCA/tropdata/photol
on HECToR, and in
/projects/um1/vn8.2/ctldata/UKCA/tropdata/photol
on MONSooN. To use this scheme, in the UMUI go to Model Selection → Atmosphere → Model Configuration → UKCA Chemistry and Aerosols → PHOTO and click 2D Photolysis Scheme. You will then need to give the location of the files (above). The code controlling this scheme is held in ukca_phot2d.F90.
It is advised that this scheme is no longer used, and interactive photolysis should be used instead. For the CheST/StratTrop scheme, Fast-JX should be used as this covers the stratosphere as well as the troposphere.
References
- Hough, A. M.: The calculation of photolysis rates for use in global modelling studies, Tech. rep., UK Atomic Energy Authority, Harwell, Oxon., UK, 1988
- Law, K., Plantevin, P., Shallcross, D., Rogers, H., Pyle, J., Grouhel, C., Thouret, V., and Marenco, A.: Evaluation of modeled O3 using Measurement of Ozone by Airbus In-Service Aircraft (MOZAIC) data, J. Geophys. Res., 103, 25721–25737, 1998
Stratospheric Look-Up Table Photolysis
In a chemistry scheme which has stratospheric chemistry, such as CheS/Strat and CheST/StratTrop, if interactive photolysis is not used, then above 300hPa the look-up table approach of Lary and Pyle (1991)[1] is used (below 300hPa the tropospheric scheme described above is used). To use this scheme, in the UMUI go to Model Selection → Atmosphere → Model Configuration → UKCA Chemistry and Aerosols → PHOTO and click 2D Photolysis Scheme. The code for this scheme is held in ukca_photolib.F90.
References
- Lary, D. and Pyle, J.: Diffuse-radiation, twilight, and photochemistry, J. Atmos. Chem., 13, 393–406, 1991.
Interactive Photolysis
The Fast-J scheme (Wild et al, 2000)[1] uses 7 different wavelength binx in the troposphere, and the Fast-JX scheme (Neu et al, 2007)[2] extends this into the stratosphere and uses up to 18 bins.
To use these schemes, in the UMUI go to Model Selection → Atmosphere → Model Configuration → UKCA Chemistry and Aerosols → PHOTO and click either FASTJ Photolysis Scheme or FASTJX Photolysis Scheme. You will then need to give the location of several input data files used by these schemes. The code for Fast-J is in the UKCA/ directory in the fastj_*.F90 files (controlled by ukca_fastj.F90), and the code for Fast-JX is in the fastjx_*.F90 files (controlled by ukca_fastjx.F90).
Further details on the Fast-JX scheme, and how it is used in UKCA, can be found in Telford et al (2013).
References
- Wild, O., Zhu, X., and Prather, M.: Fast-J: accurate simulation of in- and below-cloud photolysis in tropospheric chemical models, J. Atmos. Chem., 37, 245–282, doi:10.1023/A:1006415919030, 2000
- Neu, J., Prather, M., and Penner, J.: Global atmospheric chemistry: integrating over fractional cloud cover, J. Geophys. Res., 112, D11306, 12 pp., doi:10.1029/2006JD008007, 2007
Chemistry Defition Routines
The photolysis reactions are defined in the ukca_chem_scheme.F90 routines using the ratj_t Fortran type specification, usually in several arrays. To format of this ratj_t type is
rath_t('Reactant 1','Reactant 2','Product 1 ','Product 2 ','Product 3 ',& 'Product 4 ', Fraction of Product 1 produced, Fraction of Product 2 produced, Fraction of Product 3 produced, Fraction of Product 4 produced, Quantum Yield, Look-up Label), &
The Look-Up Label is used to define the file used for the 2D photolysis, and is used by Fast-J/Fast-JX to find the correct values for each species in the input data files. Examples of this type are
ratj_t('H2O2 ','PHOTON ','OH ','OH ',' ', & ' ', 0.0, 0.0, 0.0, 0.0, 100.000,'jh2o2 ') , & ratj_t('HCHO ','PHOTON ','HO2 ','HO2 ','CO ', & ' ', 0.0, 0.0, 0.0, 0.0, 100.000,'jhchoa ') , &
Increase the size of JPPJ (and JPNR)
As with the bimolecular, termolecular, and heterogeneous reactions, you will also need to increase the values of two parameters that UKCA needs. These are
- JPPJ is the number of photolysis reactions
- JPNR is the total number of reactions
These are set automatically in the UMUI (depending on what scheme is chosen), and are placed in the &RUN_UKCA
namelist in CNTLATM. You will need to make a hand-edit to change these accordingly. The current values can be found by saving and processing the job, and then viewing the CNTLATM file in the $HOME/umui_jobs/jobid directory.
Task 6.1: Add a bimolecular reaction
TASK 6.1: You should now add in the bimolecular reaction of ALICE with OH to form BOB. This reaction is given by:
Parameter | Value |
---|---|
2.70E-11 | |
0.00 | |
-390.00 |
Note: If you were unable to successfully complete Task 5.2, then please take a copy of the f job from the Tutorial experiment (Tutorial: solution to Task 5.2 - adding new chemical emissions into a UKCA tracer) and work from there, as this will allow you to make only the required UKCA changes.
Written by Luke Abraham 2013