TOMAS aerosol microphysics: Difference between revisions
Line 182: | Line 182: | ||
Below are some results of benchmarking GC-TOMAS with earlier versions of the model as well as observations: | Below are some results of benchmarking GC-TOMAS with earlier versions of the model as well as observations: | ||
[[Image: | [[Image:CN10_smaller.jpg]] | ||
'''Figure 1: CN10 concentrations predicted by GC-TOMAS v8-02-05 against observations. Descriptions of observational data can be found on p 5454 of Pierce et al, Atmos. Chem. Phys., 7, 2007.''' | '''Figure 1: CN10 concentrations predicted by GC-TOMAS v8-02-05 against observations. Descriptions of observational data can be found on p 5454 of Pierce et al, Atmos. Chem. Phys., 7, 2007.''' |
Revision as of 21:33, 5 March 2010
Overview
The TwO-Moment Aerosol Sectional (TOMAS) microphysics package was developed for implementation into GEOS-Chem at Carnegie-Mellon University. Using a moving sectional and moment-based approach, TOMAS tracks two independent moments (number and mass) of the aerosol size distribution for 30 size bins. It also contains codes to simulate nucleation, condensation, and coagulation processes. The aerosol species that are considered with 30-bin size resolution are sulfate, sea-salt, BC/OC, EC, and dust.
Authors and collaborators
- Peter Adams (Carnegie-Mellon U.) -- Principal Investigator
- Win Trivitayanurak (Carnegie-Mellon U. -- now at U. Edinburgh)
- Dan Westervelt (Carnegie-Mellon U.)
- Jeffrey Pierce (Dalhousie U.)
Questions regarding TOMAS can be directed at Dan (e-mail linked above).
--Dan W. 11:53, 27 January 2010 (EST)
TOMAS User Groups
User Group | Personnel | Projects |
---|---|---|
Carnegie-Mellon University | Peter Adams Dan Westervelt |
... |
Dalhousie University | Jeffrey Pierce | ... |
Tracers
TOMAS is a simulation type 3 and utilizes 310 tracers. Each aerosol species requires 30 tracers for the 30 bin size resolution. Here is the (abbreviated) default setup in input.geos (see run.Tomas directory):
Tracer # Description 40 H2SO4 41-70 Number 71-100 Sulfate 101-130 Sea-salt 131-160 Hydrophilic EC 161-190 Hydrophobic EC 191-210 Hydrophilic OC 211-240 Hydrophobic OC 241-271 Mineral dust 271-310 Aerosol water
--Dan W. 21:08, 28 January 2010 (EST)
Implementation notes
TOMAS validation in GEOS-Chem v8-02-05 was completed on 24 Feb 2010.
Code structure
The main-level Code directory has now been divided into several subdirectories:
GeosCore/ GEOS-Chem "core" routines GeosTomas/ Parallel copies of GEOS-Chem routines that reference TOMAS GeosUtil/ "Utility" modules (e.g. error_mod.f, file_mod.f, time_mod.f, etc. Headers/ Header files (define.h, CMN_SIZE, CMN_DIAG, etc.) KPP/ KPP solver directory structure bin/ Directory where executables are placed doc/ Directory where documentation is created help/ Directory for GEOS-Chem Help Screen lib/ Directory where library files are placed mod/ Directory where module files are placed obsolete/ Directory where obsolete versions of code are archived
Because there were a lot of TOMAS-related modifications in several GEOS-Chem "core" routines, the routines that need to "talk" to TOMAS were placed into a separate subdirectory named GeosTomas/. The files in GeosTomas are:
Files: ------ Makefile -- GEOS-Chem routines that have been aero_drydep.f modified to reference the TOMAS aerosol carbon_mod.f microphysics package. These are kept chemdr.f in a separate GeosTomas directory so that chemistry_mod.f they do not interfere with the routines cleanup.f in the GeosCore directory. diag3.f diag_mod.f The GeosTomas directory only needs to diag_pl_mod.f contain the files that have been modified drydep_mod.f for TOMAS. The Makefile will look for dust_mod.f all other files from the GeosCore directory emissions_mod.f using the VPATH option in GNU Make. gamap_mod.f initialize.f NOTE to GEOS-Chem developers: When you input_mod.f make changes to any of these routines isoropia_mod.f in the GeosCore directory, you must also logical_mod.f make the same modifications to the ndxx_setup.f corresponding routines in the GeosTomas planeflight_mod.f directory. seasalt_mod.f sulfate_mod.f Maybe in the near future we can work tomas_mod.f towards integrating TOMAS into the GeosCore tomas_tpcore_mod.f90 directory more cleanly. However, due to tpcore_mod.f the large number of modifications that were tpcore_window_mod.f necessary for TOMAS, it was quicker to tracerid_mod.f implement the TOMAS code in a separate wetscav_mod.f subdirectory. xtra_read_mod.f -- Bob Y. (1/25/10)
Each of these files were merged with the corresponding files in the GeosCore subdirectory. Therefore, in addition to having the GEOS-Chem modifications from v8-02-05, these files also have the relevant TOMAS references.
A few technical considerations dictated the placing of these files into a separate GeosTomas/ directory:
- The ND60 diagnostic in the standard GEOS-Chem code (in GeosCore/) is now used for the CH4 offline simulation, but in TOMAS it's used for something else.
- Some parameters needed to be declared differently with for simulations with TOMAS.
- Because not all GEOS-Chem users will choose to use TOMAS, we did not want to unnecessarily bog down the code in GeosCore/ with references to TOMAS-specific routines.
All of these concerns could be best solved by keeping parallel copies of the affected routines in the GeosTomas directory.
--Bob Y. 13:35, 25 February 2010 (EST)
Building GEOS-Chem with TOMAS
The VPATH feature of GNU Make is used to simplify the compilation. When GEOS-Chem is compiled with the TOMAS option, the GNU Make utility will search for files in the GeosTomas/ directory first. If it cannot find files there, it will then search the GeosCore/ directory. Thus, if we make a change to a "core" GEOS-Chem routine in the GeosCore/ subdirectory (say in dao_mod.f or diag49_mod.f), then those changes will automatically be applied when you build GEOS-Chem with TOMAS. Thus, we only need to keep in GeosTomas/ separate copies of those files that have to "talk" with TOMAS.
Several new targets were added to the Makefile in the top-level Code/ directory:
#============================================================================= # Targets for TOMAS aerosol microphysics code (win, bmy, 1/25/10) #============================================================================= .PHONY: tomas libtomas exetomas cleantomas tomas: @$(MAKE) -C $(GEOSTOM) TOMAS=yes all libtomas: @$(MAKE) -C $(GEOSTOM) TOMAS=yes lib exetomas: @$(MAKE) -C $(GEOSTOM) TOMAS=yes exe cleantomas: @$(MAKE) -C $(GEOSTOM) TOMAS=yes clean
You can build GEOS-Chem with the TOMAS option by typing:
make TOMAS=yes ...
This will automatically do the proper things to build the TOMAS code into GEOS-Chem, such as:
- Adding a -DTOMAS C-preprocessor switch to the FFLAGS compiler flag settings in Makefile_header.mk. This will cause TOMAS-specific areas of code to be turned on.
- Turning off OpenMP parallelization. For now the GEOS-Chem + TOMAS code needs to be run on a single processor. We continue to work on parallelizing the code.
- Calling the Makefile in the GeosTomas/ subdirectory to build the executable. The executable file is now named geostomas in order to denote that the TOMAS code is built in.
The GEOS-Chem + TOMAS has been built on the following compilers
- Intel Fortran compiler v10
- SunStudio 12
--Bob Y. 10:36, 27 January 2010 (EST)
Computational Information
GC-TOMAS v8-02-05 on a single 2.6 GHz processor:
- 36 hours of real time per month of model simulation time
- 4.3 GB RAM per simulation (with full diagnostic output)
- 3.8 GB RAM per simulation (with minimal diagnostic output)
"Full diagnostic" refers to recording output for optical depths, J-values, wet and dry deposition, tracer concentrations, and microphysical processes (nucleation rates, condensation, coagulation).
"Minimal diagnostic" refers to recording output for all of the above except wet and dry deposition.
--Dan W. 20:40, 10 February 2010 (EST)
Microphysics Routines
The aerosol microphysics code is largely contained within the file tomas_mod.f. Tomas_mod and its subroutines are modular -- they use all their own internal variables
Aerophys
The aerophys routine is where each individual microphysical process is called within the code. To efficiently calculate the competition between nucleation and condensation for H2SO4, H2SO4 concentrations are calculated using a pseudo-steady state approach as described in Pierce and Adams, 2009, AS&T. Within this routine, nucleation, condensation, and coagulation are calculated at each time step. Cond_nuc is called for coupled nucleation-condensation. Nucleation schemes can either be binary (Vehkamaki et al 2002) or ternary (Napari et al 2002). There is a switch for this in the variable declarations. For nucleation, a parameterization (Kerminen et al 2004) is used to determine the flux of new particles to the first size bin.
--Dan W. 22:36, 28 January 2010 (EST)
Validation
GC-TOMAS v8-02-05 generally compares very well with observations and other models. Please see our GC-TOMAS v8-02-05 validation document for more information and figures.
Below are some results of benchmarking GC-TOMAS with earlier versions of the model as well as observations:
Figure 1: CN10 concentrations predicted by GC-TOMAS v8-02-05 against observations. Descriptions of observational data can be found on p 5454 of Pierce et al, Atmos. Chem. Phys., 7, 2007.
Figure 2: Surface layer CCN concentrations at 0.2% supersaturation averaged over the month of January 2006.
--Dan W. 20:13, 10 February 2010 (EST)
Previous issues now resolved
Segmentation Fault
You may get an early segfault if your stacksize is not set to either unlimited or a very large number. To avoid this, you either have to change the value of an environmental variable (setenv command in .cshrc) or use the ulimit command. See this page for details.
--Dan W. 20:20, 10 February 2010 (EST)
Outstanding issues
Vertical Grids
Currently, GC-TOMAS is only compatible with the reduced vertical grids:
Development for the full vertical grids is ongoing.
--Dan W. 20:43, 10 February 2010 (EST)
Other versions of TOMAS
The above has described TOMAS in just one of its many forms. Since TOMAS is completely modular, we have a box model version available as well. Additionally, we have versions with variable size resolutions. A 40-bin version with size resolution down to 1 nm eliminates the need for a parameterization of flux of nucleated particles to the first size bin. For faster computational time, we also have a 15-bin and 12-bin version, which has already been developed in GISS GCM and is coming soon for GEOS-Chem.
--Dan W. 11:58, 19 February 2010 (EST)