Transport Simulations of Carbon Monoxide and Aerosols from Boreal Wildfires during Arctas Using WRF-Chem
The Weather Research and Forecasting Model (WRF) was developed by the National Center for Atmospheric Research as the next generation mesoscale meteorology model. The inclusion of a chemistry module (WRF-Chem) allows transport simulations of chemical and aerosol species such as those observed during...
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Oceanography Atmospheric sciences Meteorology |
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Oceanography Atmospheric sciences Meteorology Transport Simulations of Carbon Monoxide and Aerosols from Boreal Wildfires during Arctas Using WRF-Chem |
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The Weather Research and Forecasting Model (WRF) was developed by the National Center for Atmospheric Research as the next generation mesoscale meteorology model. The inclusion of a chemistry module (WRF-Chem) allows transport simulations of chemical and aerosol species such as those observed during NASA's Arctic Research of the Composition of the Troposphere from Aircraft and Satellites (ARCTAS) during 2008. The ARCTAS summer deployment phase during June and July coincided with large boreal wildfires in Saskatchewan and Eastern Russia. One of the most important aspects of simulating wildfire plume transport is the height at which emissions are injected. WRF-Chem contains an integrated one-dimensional plume rise model to determine the appropriate injection layer. The plume rise model accounts for thermal buoyancy associated with fires and the local meteorological stability. This study compares results from the plume model against those of more traditional injection methods such as filling the planetary boundary layer or a layer 3-5 km above ground level (AGL). Fire locations are satellite-derived from the GOES Wildfire Automated Biomass Burning Algorithm (WF_ABBA) and the MODIS thermal hotspot detection. Two preprocessing methods for these fires are compared: the prep_chem_sources method included with WRF-Chem, and the Naval Research Laboratory's Fire Locating and Monitoring of Burning Emissions (FLAMBE). Satellite products from the AIRS, MISR and CALIOP sensors provide data for verifying the simulations. Observed near-source plume heights from MISR's stereo-height product are compared with the plume rise model's simulated injection heights. Long range plume transport is evaluated qualitatively in the horizontal using AIRS's total column carbon monoxide product. Qualitative vertical evaluation uses CALIOP's high vertical resolution and aerosol identification algorithm. Horizontal plume structures are further tested quantitatively using an object-based methodology. The plume rise model produces the best agreement with satellite-observed injection heights. Filling the planetary boundary layer or the 3-5 km AGL layer with emissions exhibit less agreement with the observational plume heights. Results indicate that WRF-Chem can accurately transport chemical plumes throughout the ten-day simulation. However, differences in injection heights produce different transport pathways. Small differences in injection height are ameliorated when synoptic scale features such as warm conveyor belts quickly loft the emissions to higher altitudes. In scenarios where large scale lofting is delayed, the plume rise simulations creates the most accurate simulated plumes. === A Thesis Submitted to the Department of Meteorology in Partial Fulfillment of the Requirements for the Degree of Master of Science. === Summer Semester, 2010. === April 15, 2010. === Numerical Weather Prediction, ARCTAS === Includes bibliographical references. === Henry Fuelberg, Professor Directing Thesis; Guosheng Liu, Committee Member; Robert Hart, Committee Member. |
author2 |
Sessions, Walter Raymond (authoraut) |
author_facet |
Sessions, Walter Raymond (authoraut) |
title |
Transport Simulations of Carbon Monoxide and Aerosols from Boreal Wildfires during Arctas Using WRF-Chem |
title_short |
Transport Simulations of Carbon Monoxide and Aerosols from Boreal Wildfires during Arctas Using WRF-Chem |
title_full |
Transport Simulations of Carbon Monoxide and Aerosols from Boreal Wildfires during Arctas Using WRF-Chem |
title_fullStr |
Transport Simulations of Carbon Monoxide and Aerosols from Boreal Wildfires during Arctas Using WRF-Chem |
title_full_unstemmed |
Transport Simulations of Carbon Monoxide and Aerosols from Boreal Wildfires during Arctas Using WRF-Chem |
title_sort |
transport simulations of carbon monoxide and aerosols from boreal wildfires during arctas using wrf-chem |
publisher |
Florida State University |
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http://purl.flvc.org/fsu/fd/FSU_migr_etd-1805 |
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1719318055339687936 |
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ndltd-fsu.edu-oai-fsu.digital.flvc.org-fsu_1762832020-06-05T03:08:28Z Transport Simulations of Carbon Monoxide and Aerosols from Boreal Wildfires during Arctas Using WRF-Chem Sessions, Walter Raymond (authoraut) Fuelberg, Henry (professor directing thesis) Liu, Guosheng (committee member) Hart, Robert (committee member) Department of Earth, Ocean and Atmospheric Sciences (degree granting department) Florida State University (degree granting institution) Text text Florida State University Florida State University English eng 1 online resource computer application/pdf The Weather Research and Forecasting Model (WRF) was developed by the National Center for Atmospheric Research as the next generation mesoscale meteorology model. The inclusion of a chemistry module (WRF-Chem) allows transport simulations of chemical and aerosol species such as those observed during NASA's Arctic Research of the Composition of the Troposphere from Aircraft and Satellites (ARCTAS) during 2008. The ARCTAS summer deployment phase during June and July coincided with large boreal wildfires in Saskatchewan and Eastern Russia. One of the most important aspects of simulating wildfire plume transport is the height at which emissions are injected. WRF-Chem contains an integrated one-dimensional plume rise model to determine the appropriate injection layer. The plume rise model accounts for thermal buoyancy associated with fires and the local meteorological stability. This study compares results from the plume model against those of more traditional injection methods such as filling the planetary boundary layer or a layer 3-5 km above ground level (AGL). Fire locations are satellite-derived from the GOES Wildfire Automated Biomass Burning Algorithm (WF_ABBA) and the MODIS thermal hotspot detection. Two preprocessing methods for these fires are compared: the prep_chem_sources method included with WRF-Chem, and the Naval Research Laboratory's Fire Locating and Monitoring of Burning Emissions (FLAMBE). Satellite products from the AIRS, MISR and CALIOP sensors provide data for verifying the simulations. Observed near-source plume heights from MISR's stereo-height product are compared with the plume rise model's simulated injection heights. Long range plume transport is evaluated qualitatively in the horizontal using AIRS's total column carbon monoxide product. Qualitative vertical evaluation uses CALIOP's high vertical resolution and aerosol identification algorithm. Horizontal plume structures are further tested quantitatively using an object-based methodology. The plume rise model produces the best agreement with satellite-observed injection heights. Filling the planetary boundary layer or the 3-5 km AGL layer with emissions exhibit less agreement with the observational plume heights. Results indicate that WRF-Chem can accurately transport chemical plumes throughout the ten-day simulation. However, differences in injection heights produce different transport pathways. Small differences in injection height are ameliorated when synoptic scale features such as warm conveyor belts quickly loft the emissions to higher altitudes. In scenarios where large scale lofting is delayed, the plume rise simulations creates the most accurate simulated plumes. A Thesis Submitted to the Department of Meteorology in Partial Fulfillment of the Requirements for the Degree of Master of Science. Summer Semester, 2010. April 15, 2010. Numerical Weather Prediction, ARCTAS Includes bibliographical references. Henry Fuelberg, Professor Directing Thesis; Guosheng Liu, Committee Member; Robert Hart, Committee Member. Oceanography Atmospheric sciences Meteorology FSU_migr_etd-1805 http://purl.flvc.org/fsu/fd/FSU_migr_etd-1805 This Item is protected by copyright and/or related rights. You are free to use this Item in any way that is permitted by the copyright and related rights legislation that applies to your use. For other uses you need to obtain permission from the rights-holder(s). The copyright in theses and dissertations completed at Florida State University is held by the students who author them. http://diginole.lib.fsu.edu/islandora/object/fsu%3A176283/datastream/TN/view/Transport%20Simulations%20of%20Carbon%20Monoxide%20and%20Aerosols%20from%20Boreal%20Wildfires%20during%20Arctas%20Using%20WRF-Chem.jpg |