GEOS-Chem Adjoint Model: Difference between revisions
Line 29: | Line 29: | ||
=== GEOS-Chem v6-02-05, full chemistry with online aerosols === | === GEOS-Chem v6-02-05, full chemistry with online aerosols === | ||
==== Features ==== | ==== Features ==== | ||
* GEOS-3 | * GEOS-3 met fields | ||
* 4x5 | * 4x5 model resolution | ||
* Observational Operators | * Observational Operators | ||
** IMPROVE PM2.5 (NO3, SO4, OC, BC) | ** IMPROVE PM2.5 (NO3, SO4, OC, BC) | ||
Line 38: | Line 38: | ||
*** using Dalhousie retrieval (Shim) | *** using Dalhousie retrieval (Shim) | ||
* Control parameters | * Control parameters | ||
** Emissions (SOx, NOx, NH3, BC, OC | ** Emissions (SOx, NOx, NH3, BC, OC) | ||
*** now includes lightning NOx | *** now includes lightning NOx | ||
*** now includes soil NOx | *** now includes soil NOx |
Revision as of 01:27, 29 March 2008
General
Historical Overview
Original work on the adjoint of GEOS-Chem began in 2003, focusing on the adjoint of the offline aerosol simulation. By 2005, the adjoint was expanded to include a tagged CO simulation and a full chemistry simulation as well as observational operators for MOPITT (CO) and IMPROVE network(aerosols). The adjoint code has been constructed in a hybrid fashion using a combination of automatic differentiation software (TAMC, KPP) and manual coding of both discrete and continuous adjoints. Current development aims to standardize the implementation of the adjoint model and make it more user friendly, with the eventual goal of making the adjoint publicly available as part of the standard GEOS-Chem code base.
Developers
- Caltech: John Seinfeld
- Carleton University: Amir Hakami
- Columbia / NASA GISS / CU Boulder : Daven Henze
- Dalhousie: Randall Martin, Chulkyu Lee
- Harvard: Monika Kopacz, Daniel Jacob
- JPL: Kevin Bowman, Qinbin Li, Xun Jiang, Changsub Shim, Yang Chen, Sunita Verma
- U. of Toronto: Dylan Jones, Mark Parrington, Michael Seymour
- Virginia Tech: Adrian Sandu, Kumaresh Singh, Paul Eller
Current Activities
- to add
Get Involved
Support and development of the GEOS-Chem adjoint has clearly become a multifaceted undertaking. In attempt to focus such developments, we've created a GC-adjoint mailing list. If you wish to become involved, you should add yourself to this list by sending an email to geos-chem-adjoint-requests@geos.as.harvard.edu with the word subscribe in the subject or body.
Kevin Bowman organizes bimonthly conference calls concerning current adjoint model activities.
Adjoint Model Branches
There are currently three main branches of the GEOS-Chem adjoint model.
- GEOS-Chem v6-02-05, full chemistry with online aerosols
- GEOS-Chem v6/v7, tagged CO/CO2
- GEOS-Chem v7, full chemistry
GEOS-Chem v6-02-05, full chemistry with online aerosols
Features
- GEOS-3 met fields
- 4x5 model resolution
- Observational Operators
- IMPROVE PM2.5 (NO3, SO4, OC, BC)
- CASTNet (NH4+)
- GOME / SCIAMACHY NO2 column
- using KNMI retrieval (Henze)
- using Dalhousie retrieval (Shim)
- Control parameters
- Emissions (SOx, NOx, NH3, BC, OC)
- now includes lightning NOx
- now includes soil NOx
- working on volcano SO2 (C. Lee)
- Initial Conditions
- Reaction Rate Parameters
- Emissions (SOx, NOx, NH3, BC, OC)
- Code manual
- Code diagrams
Primary Developer
Daven Henze
Publications
- Henze, D. K., A. Hakami and J. H. Seinfeld (2007), Development of the adjoint of GEOS-Chem, Atmos. Chem. Phys., 7, 2413-2433.
GEOS-Chem v6/v7, tagged CO/CO2
Features
- GEOS-3, GEOS-4 met fields
- 4x5, 2x2.5 model resolution
- Observational Operators
- MOPITT CO column
- SCIAMACHY CO colum
- using Bremen retrieval
- using SRON (Dutch) retrieval
- AIRS CO column
Primary Developer
Monika Kopacz
Publications
- Kopacz, M., D. J. Jacob, D. K. Henze, C. L. Heald, D. G. Streets, and Q. Zhang (2008), A comparison of analytical and adjoint Bayesian inversion methods for constraining Asian sources of CO using satellite (MOPITT) measurements of CO columns, J. Geophys. Res., doi:0.1029/2007JD009264.
GEOS-Chem v7, full chemistry
NOTE: this version is currently under development
Features
- GEOS-3, GEOS-4, GEOS-5 met fields
- 4x5, 2x2.5 model resolution
- Observational Operators
- TES O3
Primary Developer
Kumaresh Singh