GEOS-Chem benchmarking: Difference between revisions

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!bgcolor="#cccccc"|Vertical Resolution:
!bgcolor="#cccccc"|[[GEOS-Chem_vertical_grids|Vertical Resolution]]:
|GEOS-FP with 72 hybrid sigma-pressure levels
|[[GEOS-FP]] with [[GEOS-Chem_vertical_grids#72-layer_vertical_grid|72 hybrid sigma-pressure levels]]


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|-valign="top"
!bgcolor="#cccccc"|Horizontal Resolution:
!bgcolor="#cccccc"|[[GEOS-Chem_horizontal_grids|Horizontal Resolution]]:
|4° latitude x 5° longitude
|[[GEOS-Chem_horizontal_grids#GMAO_4_x_5_grid|4° latitude x 5° longitude]]


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|-valign="top"
!bgcolor="#cccccc"|Advected species:
!bgcolor="#cccccc"|Advected [[Species_in_GEOS-Chem#Full-chemistry|species]]:
|<u>Gas-phase tracers:</u>
|<u>Gas-phase species:</u>
NO, O3, PAN, CO, Lumped >=C4 Alkanes, ISOP, HNO3, H2O2, MEK, Acetaldehyde, Lumped Aldehyde >=C3, MVK, Methacrolein, PMN, PPN, Lumped Alkyl Nitrate, >=C3 Alkenes, C3H8, HCHO, C2H6, N2O5, HNO4, Methyl Hydro Peroxide, DMS, SO2, SO4, MSA, NH3, NH4, NIT, MPN, ISOPN, MOBA, PROPNN, HAC, GLYC, MMN, RIP, IEPOX, MAP, NO2, NO3, HNO2
NO, O3, PAN, CO, Lumped >=C4 Alkanes, ISOP, HNO3, H2O2, MEK, Acetaldehyde, Lumped Aldehyde >=C3, MVK, Methacrolein, PMN, PPN, Lumped Alkyl Nitrate, >=C3 Alkenes, C3H8, HCHO, C2H6, N2O5, HNO4, Methyl Hydro Peroxide, DMS, SO2, SO4, MSA, NH3, NH4, NIT, MPN, ISOPN, MOBA, PROPNN, HAC, GLYC, MMN, RIP, IEPOX, MAP, NO2, NO3, HNO2


<u>Aerosol tracers:</u>
<u>Aerosol species:</u>
DMS, SO2, SO4, MSA, NH3, NH4, NIT, Hydrophilic BC, Hydrophilic OC, Hydrophobic BC, Hydrophobic OC, Dust Aerosol (4 size bins), Sea Salt Aerosol (2 size bins), SO4s (SO4 on the surface of sea salt aerosol), NITs (NIT on the surface of sea salt aerosol)
DMS, SO2, SO4, MSA, NH3, NH4, NIT, Hydrophilic BC, Hydrophilic OC, Hydrophobic BC, Hydrophobic OC, Dust Aerosol (4 size bins), Sea Salt Aerosol (2 size bins), SO4s (SO4 on the surface of sea salt aerosol), NITs (NIT on the surface of sea salt aerosol)


<u>Bromine tracers:</u>
<u>Bromine species:</u>
Br2, Br, BrO, HOBr, HBr, BrNO2 BrNO3, CHBr3, CH2Br2, CH3Br
Br2, Br, BrO, HOBr, HBr, BrNO2 BrNO3, CHBr3, CH2Br2, CH3Br


<u>Stratospherically-important tracers</u>
<u>Stratospherically-important species</u>
N2O, OCS, CH4, BrCl, HCl, CCl4, CH3Cl, CH3CCl3, CFCX, HCFCX, CFC11, CFC12, HCFC22, H1211, H2402, Cl, ClO, HOCl, ClNO3, ClNO2, ClOO, OClO, Cl2, Cl202, H2O
N2O, OCS, CH4, BrCl, HCl, CCl4, CH3Cl, CH3CCl3, CFCX, HCFCX, CFC11, CFC12, HCFC22, H1211, H2402, Cl, ClO, HOCl, ClNO3, ClNO2, ClOO, OClO, Cl2, Cl202, H2O


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|-valign="top"
!bgcolor="#cccccc"|Chemical Mechanism:
!bgcolor="#cccccc"|[[GEOS-Chem_chemistry_mechanisms|Chemical Mechanism]]:
|KPP (Eller et al., 2009) using the UCX chemistry mechanism (Eastham et al, 2014).<br>Chemistry is done in both the troposphere and the stratosphere.
|[[FlexChem]] chemical solver<br> using the standard chemistry mechanism ([[NOx-Ox-HC-Aer-Br_chemistry_mechanism|NOx-Ox-HC-Aer-Br]] + [[UCX_chemistry_mechanism|UCX]] + [[Secondary_organic_aerosols#Complex_SOA_scheme|complex SOA]])<br>Chemistry is done in both the troposphere and the stratosphere.


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!bgcolor="#cccccc"|Photolysis Mechanism:
!bgcolor="#cccccc"|[[FAST-JX_v7.0_photolysis_mechanism|Photolysis Mechanism]]:
|FAST-JX v7.0 algorithm (Prather, 2012, Wild et al, 2000).
|[[FAST-JX_v7.0_photolysis_mechanism|FAST-JX v7.0]] (Prather, 2012, Wild et al, 2000).


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!bgcolor="#cccccc"|Operations:
!bgcolor="#cccccc"|Operations:
|
|
*Advection
*[[Advection scheme TPCORE|Advection]]
*Aerosol Thermodynamical Equilibriium
*[[ISORROPIA II|Aerosol thermodynamical equilibriium]]
*Boundary Layer Mixing
*[[Boundary layer mixing]]
*Chemistry
*[[Chemistry Issues|Chemistry]]
*Cloud Convection (with updraft scavenging)
*[[Cloud convection]] (with updraft scavenging)
*Dry Deposition
*[[Dry deposition]]
*Emissions
*[[Emissions overview|Emissions]]
*Photolysis
*[[Photolysis_mechanism|Photolysis]]
*Wet Deposition
*[[Wet deposition]]


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|-valign="top"
!bgcolor="#cccccc"|Diagnostic Output:
!bgcolor="#cccccc"|[[List_of_diagnostics_for_v11-01|Diagnostic Output]]:
|All diagnostics above are saved as monthly means.
|All diagnostics above are saved as monthly means.
*Sulfate production and loss quantities
*Sulfate production and loss quantities

Revision as of 21:23, 15 August 2017

Overview

The following GEOS-Chem benchmarking procedure was adopted at the 5th International GEOS-Chem Meeting (May 2011).

  1. Any change to the GEOS-Chem source code will require a dedicated 1-month benchmark with the standard chemistry mechanism and a version update code a, b, c, etc. (such as v10-01a, v10-01b, etc). These letter codes are for internal use only and do not represent a version release. The benchmark results will be posted publicly with an email sent to the GEOS-Chem Steering Committee.
  2. The developer(s) will assess the benchmark results by filling out a form (created by Colette Heald and adapted to a wiki page) for all to see. If the developer has any concerns about the benchmark results they will contact the GEOS-Chem Support Team, the relevant GEOS-Chem Working Group Chairs, and/or Model Scientist Daniel Jacob. GEOS-Chem Steering Committee members are also encouraged to examine and comment on the benchmark results.
  3. Once the developer is satisfied with the changes in the 1-month benchmark, GEOS-Chem Model Scientist Daniel Jacob will promptly review the results and approve the new internal version.
  4. 1-year benchmarks for internal version updates will be conducted only if justifiably requested by the developer or by GEOS-Chem Steering Committee members.
  5. Each new public version release (e.g. GEOS-Chem v10-01) will be subject to a 1-year benchmark to be inspected by the GEOS-Chem Steering Committee before approval. Changes will be bundled so that we will have new versions released every 9 months or so — this has been our rhythm in recent years.

1-month benchmark

Overview

Dates of run: July 1, 2013 – August 1, 2013
Vertical Resolution: GEOS-FP with 72 hybrid sigma-pressure levels
Horizontal Resolution: 4° latitude x 5° longitude
Advected species: Gas-phase tracers:

NO, O3, PAN, CO, Lumped >=C4 Alkanes, ISOP, HNO3, H2O2, MEK, Acetaldehyde, Lumped Aldehyde >=C3, MVK, Methacrolein, PMN, PPN, Lumped Alkyl Nitrate, >=C3 Alkenes, C3H8, HCHO, C2H6, N2O5, HNO4, Methyl Hydro Peroxide, DMS, SO2, SO4, MSA, NH3, NH4, NIT, MPN, ISOPN, MOBA, PROPNN, HAC, GLYC, MMN, RIP, IEPOX, MAP, NO2, NO3, HNO2

Aerosol tracers: DMS, SO2, SO4, MSA, NH3, NH4, NIT, Hydrophilic BC, Hydrophilic OC, Hydrophobic BC, Hydrophobic OC, Dust Aerosol (4 size bins), Sea Salt Aerosol (2 size bins), SO4s (SO4 on the surface of sea salt aerosol), NITs (NIT on the surface of sea salt aerosol)

Bromine tracers: Br2, Br, BrO, HOBr, HBr, BrNO2 BrNO3, CHBr3, CH2Br2, CH3Br

Stratospherically-important tracers N2O, OCS, CH4, BrCl, HCl, CCl4, CH3Cl, CH3CCl3, CFCX, HCFCX, CFC11, CFC12, HCFC22, H1211, H2402, Cl, ClO, HOCl, ClNO3, ClNO2, ClOO, OClO, Cl2, Cl202, H2O

Chemical Mechanism: FlexChem chemical solver
using the standard chemistry mechanism (NOx-Ox-HC-Aer-Br + UCX + complex SOA)
Chemistry is done in both the troposphere and the stratosphere.
Photolysis Mechanism: FAST-JX v7.0 (Prather, 2012, Wild et al, 2000).
Operations:
Diagnostic Output: The following diagnostic outputs are archived as monthly means
  • Sulfate production and loss quantities
  • Dust aerosol sources
  • Carbon aerosol sources
  • Sea salt aerosol sources
  • Acetone sources
  • Sulfur sources
  • Optical Depths
  • Noontime J-values
  • Biomass burning emission fluxes
  • CO sources
  • Surface Pressure
  • NOx sources
  • Biofuel emission fluxes
  • Anthropogenic emission fluxes
  • Scavenging loss from moist convection
  • Scavenging loss from wet deposition
  • Concentrations of chemically produced OH and HO2
  • Dry deposition fluxes and velocities
  • Tracer concentrations
  • Biogenic emission fluxes
  • Tropopause height
  • DAO 3-D met fields
  • DAO 2-D met fields
  • Air masses and grid box heights
  • Surface area
  • Lifetime of Methylchloroform (CH3CCl3)
Benchmark Plots and Summaries: The following plots, budgets, and totals are created from the oxidant-aerosol simulation:
  • Budget of Ox and CO
  • Mean OH concentration
  • Methyl Chloroform Lifetime (w/r/t loss by tropospheric OH)
  • Aerosol optical depth maps (this benchmark)
  • Aerosol optical depth differences (this benchmark - previous benchmark)
  • Concentration maps (this benchmark) of tracers + OH + HO2 at the surface and at 500 hPa
  • Difference maps (this benchmark - previous benchmark) of tracers + OH + HO2 at the surface and at 500 hPa
  • Summary of emission totals (this benchmark vs. previous benchmark)
  • Emissions maps (this benchmark) for all emitting tracers
  • Emissions difference maps (this benchmark - previous benchmark) for all emitting tracers
  • Emissions ratio maps (this benchmark / previous benchmark) for all emitting tracers
  • Frequency distribution histogram of ratios (this benchmark vs previous benchmark) for tracers, OH, and optical depths
  • J-value maps (this benchmark)
  • J-value difference maps (this benchmark - previous benchmark)
  • J-value ratio maps (this benchmark / previous benchmark)
  • Ratio maps (this benchmark / previous benchmark) of tracers + OH + HO2 at the surface and at 500 hPa
  • Zonal mean concentration maps (this benchmark) of tracers + OH + HO2
  • Zonal mean difference maps (this benchmark - previous benchmark) of tracers + OH + HO2

Plotting routines

NOTE: The 1-month benchmark plotting routines are currently written in IDL. We are planning on moving these routines to Python for the GEOS-Chem v11-02 release as part of the GCPy package.

The 1-month benchmark plotting routines are included with the GAMAP. For more information, see the this page in the GAMAP manual.

1-year benchmark

Overview

Spin-up: January 1, 2013 – January 1, 2014
Dates of Run: January 1, 2013 – January 1, 2014
Vertical Resolution: GEOS-FP with 72 hybrid sigma-pressure levels
Horizontal Resolution: 4° latitude x 5° longitude
Advected species: Gas-phase species:

NO, O3, PAN, CO, Lumped >=C4 Alkanes, ISOP, HNO3, H2O2, MEK, Acetaldehyde, Lumped Aldehyde >=C3, MVK, Methacrolein, PMN, PPN, Lumped Alkyl Nitrate, >=C3 Alkenes, C3H8, HCHO, C2H6, N2O5, HNO4, Methyl Hydro Peroxide, DMS, SO2, SO4, MSA, NH3, NH4, NIT, MPN, ISOPN, MOBA, PROPNN, HAC, GLYC, MMN, RIP, IEPOX, MAP, NO2, NO3, HNO2

Aerosol species: DMS, SO2, SO4, MSA, NH3, NH4, NIT, Hydrophilic BC, Hydrophilic OC, Hydrophobic BC, Hydrophobic OC, Dust Aerosol (4 size bins), Sea Salt Aerosol (2 size bins), SO4s (SO4 on the surface of sea salt aerosol), NITs (NIT on the surface of sea salt aerosol)

Bromine species: Br2, Br, BrO, HOBr, HBr, BrNO2 BrNO3, CHBr3, CH2Br2, CH3Br

Stratospherically-important species N2O, OCS, CH4, BrCl, HCl, CCl4, CH3Cl, CH3CCl3, CFCX, HCFCX, CFC11, CFC12, HCFC22, H1211, H2402, Cl, ClO, HOCl, ClNO3, ClNO2, ClOO, OClO, Cl2, Cl202, H2O

Chemical Mechanism: FlexChem chemical solver
using the standard chemistry mechanism (NOx-Ox-HC-Aer-Br + UCX + complex SOA)
Chemistry is done in both the troposphere and the stratosphere.
Photolysis Mechanism: FAST-JX v7.0 (Prather, 2012, Wild et al, 2000).
Operations:
Diagnostic Output: All diagnostics above are saved as monthly means.
  • Sulfate production and loss quantities
  • Dust aerosol sources
  • Carbon aerosol sources
  • Sea salt aerosol sources
  • Acetone sources
  • Sulfur sources
  • Optical Depths
  • Noontime J-values
  • Transport fluxes (N/S, E/W, up/down)
  • Biomass burning emission fluxes
  • CO sources
  • Surface Pressure
  • NOx sources
  • Biofuel emission fluxes
  • Anthropogenic emission fluxes
  • Scavenging loss from moist convection
  • Scavenging loss from wet deposition
  • Concentrations of chemically produced OH and HO2
  • Dry deposition fluxes and velocities
  • Tracer concentrations
  • Biogenic emission fluxes
  • Tropopause height
  • DAO 3-D met fields
  • DAO 2-D met fields
  • Air masses and grid box heights
  • Surface area
  • Lifetime of Methylchloroform (CH3CCl3)
  • Satellite timeseries of BrO, cloud fraction, and cloud top height
Benchmark Plots: The following plots compare advected species from 3 different benchmark simulations (versions 1-3, where version 3 is the current benchmark version). Plots are created for January, April, July, and October.
  • Aerosol optical depth maps (version 1, version 2, and version 3)
  • Emission maps (version 1, version 2, and version 3)
  • Emisison difference maps (version 3 - version 1, version 3 - version 2)
  • Emission ratio maps (version 3 / version 1, version 3 / version 2)
  • J-value maps (version 1, version 2, and version 3)
  • J-value difference maps (version 3 - version 1, version 3 - version 2)
  • J-value ratio maps (version 3 / version 1, version 3 / version 2)
  • Tracer difference maps at the surface and 500 hPa (version 3 - version 1, version 3 - version 2)
  • Tracer ratio maps at the surface and 500 hPa (version 3 / version 1, version 3 / version 2)
  • Tracer difference profiles along longitude slices (15S, 42N) (version 3 - version 1, version 3 - version 2)

The following plots show data from 3 benchmark simulations side-by-side with observations. GEOS-Chem output is plotted in red for version 1, in green for version 2, and in blue for version 3 (current benchmark version)

  • BrO seasonal columns vs. observations
  • C2H6 vertical profiles vs. observations from various aircraft campaigns
  • C3H8 vertical profiles vs. observations from various aircraft campaigns
  • CO seasonal cycle at the surface vs. MOZAIC observations
  • CO vertical profiles vs. MOZAIC observations
  • CO vertical profiles vs. various sonde observations
  • H2O2 vertical profiles vs. observations from various aircraft campaigns
  • IMPROVE difference maps (benchmark simulation output vs. surface sites)
  • IMPROVE scatter plots (benchmark simulation output vs. surface sites)
  • HNO3 vertical profiles vs. observations from various aircraft campaigns
  • NO vertical profiles vs. observations from various aircraft campaigns
  • O3 seasonal cycle @ the surface vs. MOZAIC observations
  • O3 seasonal cycle @ 300, 500, and 800 hPa vs. MOZAIC observations
  • O3 seasonal cycle @ 300, 500, and 800 hPa vs. sonde observations
  • O3 seasonal cycle @ 150, 300, 500,and 800 hPa vs. sonde observations
  • O3 vertical profiles vs. observations from various aircraft campaigns
  • O3 vertical profiles vs. observations from various aircraft campaigns
  • O3 vertical profiles vs. various sonde observations
  • O3 vertical profiles vs. MOZAIC observations
  • PAN vertical profiles vs. observations from various aircraft campaigns
  • PM2.5 difference maps (benchmark simulation output vs. surface sites)
  • PM2.5 scatter plots (benchmark simulation output vs. surface sites)

Plotting routines

NOTE: The 1-month benchmark plotting routines are currently written in IDL. We are planning on moving these routines to Python for the GEOS-Chem v11-02 release as part of the GCPy package.

The 1-year benchmark plotting routines can be downloaded from Bitbucket via Git using: 

 git clone https://bitbucket.org/gcst/gc_1yr_benchmark

The data files needed for the plots are included in the repository and are discussed in more detail below.

Observations

Retrieved from "https://wiki.seas.harvard.edu/geos-chem/index.php?title=GEOS-Chem_benchmarking&oldid=33886"