Global Terrestrial Mercury Model: Difference between revisions
No edit summary |
|||
(22 intermediate revisions by 3 users not shown) | |||
Line 1: | Line 1: | ||
On this page we describe the Global Terrestrial Mercury Model (GTMM), which is an option in the current GEOS-Chem mercury simulation. | <span style="color:red">'''''GTMM has not been supported since [[GEOS-Chem v10-01]]. If you are interested in using this simulation, please contact the [[Hg and POPs Working Group]].'''''</span> | ||
On this page we describe the Global Terrestrial Mercury Model (GTMM), which is an option in the current [[Mercury|GEOS-Chem mercury simulation]]. | |||
== Overview == | == Overview == | ||
Line 7: | Line 9: | ||
From [http://acmg.seas.harvard.edu/publications/smithdowney2009.pdf ''Smith‐Downey et al'' (2010)]: | From [http://acmg.seas.harvard.edu/publications/smithdowney2009.pdf ''Smith‐Downey et al'' (2010)]: | ||
<blockquote>The global terrestrial mercury model (GTMM) is a global 1° × 1° biogeochemical model of mercury accumulation and emissions that we apply to the continuous evolution of soil mercury from preindustrial to present day with a monthly time step. Figure 1 presents an overview of the model. Mercury is deposited to the land surface as either wet deposition of Hg(II) or dry deposition of Hg(II) and Hg0. Monthly deposition of Hg(II) and Hg0 are taken from the mercury simulation in the GEOS‐Chem chemical transport model [Selin et al., 2008]. GEOS‐Chem also includes a small deposition flux of Hg(p) emitted by combustion; this Hg(p) is not considered available for terrestrial cycling. In the model, dry deposition of Hg0 and Hg(II) can be fixed into the interior of leaves or remain on leaf and soil surfaces. Hg(II) on leaf and soil surfaces is subject to photoreduction, and Hg0 is subject to revolatilization. Wet deposition of Hg(II) and Hg(II) washed off of leaf and soil surfaces enters soils and can bind to reduced sulfur groups in organic material. At this point, the cycling of mercury in organic soils is controlled by the cycling of carbon and is modeled within the carbon cycling framework of the CASA biogeochemical model [Potter et al., 1993; van der Werf et al., 2003, 2006].We use the GEOS‐Chem mercury simulation as described by Selin et al. [2008] to supply monthly, spatially resolved, and speciated dry and wet mercury deposition fluxes to the GTMM.</blockquote> | <blockquote>The global terrestrial mercury model (GTMM) is a global 1° × 1° biogeochemical model of mercury accumulation and emissions that we apply to the continuous evolution of soil mercury from preindustrial to present day with a monthly time step. Figure 1 presents an overview of the model. Mercury is deposited to the land surface as either wet deposition of Hg(II) or dry deposition of Hg(II) and Hg0. Monthly deposition of Hg(II) and Hg0 are taken from the mercury simulation in the GEOS‐Chem chemical transport model [Selin et al., 2008]. GEOS‐Chem also includes a small deposition flux of Hg(p) emitted by combustion; this Hg(p) is not considered available for terrestrial cycling. In the model, dry deposition of Hg0 and Hg(II) can be fixed into the interior of leaves or remain on leaf and soil surfaces. Hg(II) on leaf and soil surfaces is subject to photoreduction, and Hg0 is subject to revolatilization. Wet deposition of Hg(II) and Hg(II) washed off of leaf and soil surfaces enters soils and can bind to reduced sulfur groups in organic material. At this point, the cycling of mercury in organic soils is controlled by the cycling of carbon and is modeled within the carbon cycling framework of the CASA biogeochemical model [Potter et al., 1993; van der Werf et al., 2003, 2006]. We use the GEOS‐Chem mercury simulation as described by Selin et al. [2008] to supply monthly, spatially resolved, and speciated dry and wet mercury deposition fluxes to the GTMM.</blockquote> | ||
=== Authors and collaborators: === | === Authors and collaborators: === | ||
Line 18: | Line 20: | ||
#GTMM has been implemented into [[GEOS-Chem v8-03-02]] by Claire Carouge. | #GTMM has been implemented into [[GEOS-Chem v8-03-02]] by Claire Carouge. | ||
#The input files provided with the code are those described by Smith-Downey et al | #The input files provided with the code are those described by [http://acmg.seas.harvard.edu/publications/smithdowney2009.pdf Smith-Downey et al (2010)]. | ||
#The mercury deposition comes from the Selin et al. 2008 version of the atmospheric mercury simulation. | #The mercury deposition comes from the Selin et al. 2008 version of the atmospheric mercury simulation. | ||
#Meteorology inputs are from GEOS-4. | #Meteorology inputs are from GEOS-4. | ||
#If a user wishes to run the model with the v8-03-02 version of the code (Holmes et al. 2010, Soerensen et al. 2010), then a new spin-up from the preindustrial with new input files is recommended. Contact corbitt [at] seas [dot] harvard [dot] edu for more information. (I've done a preliminary spin-up and coupled run using v8-03-02 mercury deposition inputs, but have not redone the meteorology inputs with GEOS-5 yet - eds) | #If a user wishes to run the model with the v8-03-02 version of the code (Holmes et al. 2010, Soerensen et al. 2010), then a new spin-up from the preindustrial with new input files is recommended. Contact corbitt [at] seas [dot] harvard [dot] edu for more information. (I've done a preliminary spin-up and coupled run using v8-03-02 mercury deposition inputs, but have not redone the meteorology inputs with GEOS-5 yet - eds) | ||
== Validation == | == Validation == | ||
Line 33: | Line 33: | ||
=== Journal Articles === | === Journal Articles === | ||
#Smith‐Downey, N. V, E. M. Sunderland, and D. J. Jacob, ''Anthropogenic impacts on global storage and emissions of mercury from terrestrial soils: Insights from a new global model'', <u>J. Geophys. Res.</u>, '''115''', G03008, doi:10.1029/2009JG001124, 2010. [http://acmg.seas.harvard.edu/publications/ | #Selin, N.E. and D.J. Jacob. ''Seasonal and spatial patterns of mercury wet deposition in the United States: North American vs. intercontinental sources'', <u>Atmospheric Environment</u>, '''42''', 5193-5204, 2008. [http://acmg.seas.harvard.edu/publications/2008/selin2008b.pdf (PDF)] | ||
#Smith‐Downey, N. V, E. M. Sunderland, and D. J. Jacob, ''Anthropogenic impacts on global storage and emissions of mercury from terrestrial soils: Insights from a new global model'', <u>J. Geophys. Res.</u>, '''115''', G03008, doi:10.1029/2009JG001124, 2010. [http://acmg.seas.harvard.edu/publications/2010/smithdowney2010.pdf (PDF)] | |||
#Soerensen, A.L., E.M. Sunderland, C.D. Holmes, D.J. Jacob, R. Yantosca, H. Skov, J. Christensen, S.A. Strode, and R.P. Mason, ''An Improved Global Model for Air-Sea Exchange of Mercury: High Concentrations over the North Atlantic'', <u>Env. Sci. and Tech.</u>, 44, 8574-8580, 2010. [http://acmg.seas.harvard.edu/publications/2010/soerensen2010b.pdf (PDF)] | |||
=== Documentation === | === Documentation === | ||
[http://acmg.seas.harvard.edu/geos/doc/GTMM/GTMM_manual_20100811.pdf GTMM User's Manual (11 August 2010)] | |||
Latest revision as of 14:49, 18 October 2023
GTMM has not been supported since GEOS-Chem v10-01. If you are interested in using this simulation, please contact the Hg and POPs Working Group.
On this page we describe the Global Terrestrial Mercury Model (GTMM), which is an option in the current GEOS-Chem mercury simulation.
Overview
Description
From Smith‐Downey et al (2010):
The global terrestrial mercury model (GTMM) is a global 1° × 1° biogeochemical model of mercury accumulation and emissions that we apply to the continuous evolution of soil mercury from preindustrial to present day with a monthly time step. Figure 1 presents an overview of the model. Mercury is deposited to the land surface as either wet deposition of Hg(II) or dry deposition of Hg(II) and Hg0. Monthly deposition of Hg(II) and Hg0 are taken from the mercury simulation in the GEOS‐Chem chemical transport model [Selin et al., 2008]. GEOS‐Chem also includes a small deposition flux of Hg(p) emitted by combustion; this Hg(p) is not considered available for terrestrial cycling. In the model, dry deposition of Hg0 and Hg(II) can be fixed into the interior of leaves or remain on leaf and soil surfaces. Hg(II) on leaf and soil surfaces is subject to photoreduction, and Hg0 is subject to revolatilization. Wet deposition of Hg(II) and Hg(II) washed off of leaf and soil surfaces enters soils and can bind to reduced sulfur groups in organic material. At this point, the cycling of mercury in organic soils is controlled by the cycling of carbon and is modeled within the carbon cycling framework of the CASA biogeochemical model [Potter et al., 1993; van der Werf et al., 2003, 2006]. We use the GEOS‐Chem mercury simulation as described by Selin et al. [2008] to supply monthly, spatially resolved, and speciated dry and wet mercury deposition fluxes to the GTMM.
Authors and collaborators:
- Nicole Smith-Downey (U. Austin) -- Principal Investigator
- Chris Holmes (Harvard)
- Bess Corbitt (Harvard)
- Helen Amos (Harvard)
Implementation notes
- GTMM has been implemented into GEOS-Chem v8-03-02 by Claire Carouge.
- The input files provided with the code are those described by Smith-Downey et al (2010).
- The mercury deposition comes from the Selin et al. 2008 version of the atmospheric mercury simulation.
- Meteorology inputs are from GEOS-4.
- If a user wishes to run the model with the v8-03-02 version of the code (Holmes et al. 2010, Soerensen et al. 2010), then a new spin-up from the preindustrial with new input files is recommended. Contact corbitt [at] seas [dot] harvard [dot] edu for more information. (I've done a preliminary spin-up and coupled run using v8-03-02 mercury deposition inputs, but have not redone the meteorology inputs with GEOS-5 yet - eds)
Validation
Text to be added
References
Journal Articles
- Selin, N.E. and D.J. Jacob. Seasonal and spatial patterns of mercury wet deposition in the United States: North American vs. intercontinental sources, Atmospheric Environment, 42, 5193-5204, 2008. (PDF)
- Smith‐Downey, N. V, E. M. Sunderland, and D. J. Jacob, Anthropogenic impacts on global storage and emissions of mercury from terrestrial soils: Insights from a new global model, J. Geophys. Res., 115, G03008, doi:10.1029/2009JG001124, 2010. (PDF)
- Soerensen, A.L., E.M. Sunderland, C.D. Holmes, D.J. Jacob, R. Yantosca, H. Skov, J. Christensen, S.A. Strode, and R.P. Mason, An Improved Global Model for Air-Sea Exchange of Mercury: High Concentrations over the North Atlantic, Env. Sci. and Tech., 44, 8574-8580, 2010. (PDF)