Combining Dispersion Modeling and Monitoring Data for Community-Scale Air Quality Characterization

Spatially and temporally resolved air quality characterization is critical for community-scale exposure studies and for developing future air quality mitigation strategies. Monitoring-based assessments can characterize local air quality when enough monitors are deployed. However, modeling plays a vi...

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Autores principales: Isakov, Vlad, Arunachalam, Saravanan, Baldauf, Richard, Breen, Michael, Deshmukh, Parikshit, Hawkins, Andy, Kimbrough, Sue, Krabbe, Stephen, Naess, Brian, Serre, Marc, Valencia, Alejandro
Formato: Online Artículo Texto
Lenguaje:English
Publicado: 2019
Materias:
Article
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6859648/
https://www.ncbi.nlm.nih.gov/pubmed/31741750
http://dx.doi.org/10.3390/atmos10100610
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author Isakov, Vlad
Arunachalam, Saravanan
Baldauf, Richard
Breen, Michael
Deshmukh, Parikshit
Hawkins, Andy
Kimbrough, Sue
Krabbe, Stephen
Naess, Brian
Serre, Marc
Valencia, Alejandro
author_facet Isakov, Vlad
Arunachalam, Saravanan
Baldauf, Richard
Breen, Michael
Deshmukh, Parikshit
Hawkins, Andy
Kimbrough, Sue
Krabbe, Stephen
Naess, Brian
Serre, Marc
Valencia, Alejandro
author_sort Isakov, Vlad
collection PubMed
description Spatially and temporally resolved air quality characterization is critical for community-scale exposure studies and for developing future air quality mitigation strategies. Monitoring-based assessments can characterize local air quality when enough monitors are deployed. However, modeling plays a vital role in furthering the understanding of the relative contributions of emissions sources impacting the community. In this study, we combine dispersion modeling and measurements from the Kansas City TRansportation local-scale Air Quality Study (KC-TRAQS) and use data fusion methods to characterize air quality. The KC-TRAQS study produced a rich dataset using both traditional and emerging measurement technologies. We used dispersion modeling to support field study design and analysis. In the study design phase, the presumptive placement of fixed monitoring sites and mobile monitoring routes have been corroborated using a research screening tool C-PORT to assess the spatial and temporal coverage relative to the entire study area extent. In the analysis phase, dispersion modeling was used in combination with observations to help interpret the KC-TRAQS data. We extended this work to use data fusion methods to combine observations from stationary, mobile measurements, and dispersion model estimates.
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spelling pubmed-68596482020-01-01 Combining Dispersion Modeling and Monitoring Data for Community-Scale Air Quality Characterization Isakov, Vlad Arunachalam, Saravanan Baldauf, Richard Breen, Michael Deshmukh, Parikshit Hawkins, Andy Kimbrough, Sue Krabbe, Stephen Naess, Brian Serre, Marc Valencia, Alejandro Atmosphere (Basel) Article Spatially and temporally resolved air quality characterization is critical for community-scale exposure studies and for developing future air quality mitigation strategies. Monitoring-based assessments can characterize local air quality when enough monitors are deployed. However, modeling plays a vital role in furthering the understanding of the relative contributions of emissions sources impacting the community. In this study, we combine dispersion modeling and measurements from the Kansas City TRansportation local-scale Air Quality Study (KC-TRAQS) and use data fusion methods to characterize air quality. The KC-TRAQS study produced a rich dataset using both traditional and emerging measurement technologies. We used dispersion modeling to support field study design and analysis. In the study design phase, the presumptive placement of fixed monitoring sites and mobile monitoring routes have been corroborated using a research screening tool C-PORT to assess the spatial and temporal coverage relative to the entire study area extent. In the analysis phase, dispersion modeling was used in combination with observations to help interpret the KC-TRAQS data. We extended this work to use data fusion methods to combine observations from stationary, mobile measurements, and dispersion model estimates. 2019 /pmc/articles/PMC6859648/ /pubmed/31741750 http://dx.doi.org/10.3390/atmos10100610 Text en This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/).
spellingShingle Article
Isakov, Vlad
Arunachalam, Saravanan
Baldauf, Richard
Breen, Michael
Deshmukh, Parikshit
Hawkins, Andy
Kimbrough, Sue
Krabbe, Stephen
Naess, Brian
Serre, Marc
Valencia, Alejandro
Combining Dispersion Modeling and Monitoring Data for Community-Scale Air Quality Characterization
title Combining Dispersion Modeling and Monitoring Data for Community-Scale Air Quality Characterization
title_full Combining Dispersion Modeling and Monitoring Data for Community-Scale Air Quality Characterization
title_fullStr Combining Dispersion Modeling and Monitoring Data for Community-Scale Air Quality Characterization
title_full_unstemmed Combining Dispersion Modeling and Monitoring Data for Community-Scale Air Quality Characterization
title_short Combining Dispersion Modeling and Monitoring Data for Community-Scale Air Quality Characterization
title_sort combining dispersion modeling and monitoring data for community-scale air quality characterization
topic Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6859648/
https://www.ncbi.nlm.nih.gov/pubmed/31741750
http://dx.doi.org/10.3390/atmos10100610
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