A41K-0233
Evaluation of the Community Multiscale Air Quality Model for Simulating Winter Ozone Formation in the Uinta Basin with Intensive Oil and Gas Production
Thursday, 17 December 2015
Poster Hall (Moscone South)
Rebecca Matichuk1, Gail Tonnesen1, Deborah Luecken2, Shawn Jon Roselle2, Sergey L Napelenok2, Kirk R Baker3, Robert Chad Gilliam4, Chris Misenis3, Benjamin Murphy3 and Donna B Schwede5, (1)Environmental Protection Agency - EPA Region 8, Office of Partnerships and Regulatory Assistance (OPRA), Denver, CO, United States, (2)U.S. EPA, RTP, NC, United States, (3)Environmental Protection Agency Research Triangle Park, Research Triangle Park, NC, United States, (4)Department of Environmental Protection, Kingston, NY, United States, (5)Environmental Protection Agency Research Triangle Park, Durham, NC, United States
Abstract:
The western United States is an important source of domestic energy resources. One of the primary environmental impacts associated with oil and natural gas production is related to air emission releases of a number of air pollutants. Some of these pollutants are important precursors to the formation of ground-level ozone. To better understand ozone impacts and other air quality issues, photochemical air quality models are used to simulate the changes in pollutant concentrations in the atmosphere on local, regional, and national spatial scales. These models are important for air quality management because they assist in identifying source contributions to air quality problems and designing effective strategies to reduce harmful air pollutants. The success of predicting oil and natural gas air quality impacts depends on the accuracy of the input information, including emissions inventories, meteorological information, and boundary conditions. The treatment of chemical and physical processes within these models is equally important. However, given the limited amount of data collected for oil and natural gas production emissions in the past and the complex terrain and meteorological conditions in western states, the ability of these models to accurately predict pollution concentrations from these sources is uncertain. Therefore, this presentation will focus on understanding the Community Multiscale Air Quality (CMAQ) model’s ability to predict air quality impacts associated with oil and natural gas production and its sensitivity to input uncertainties. The results will focus on winter ozone issues in the Uinta Basin, Utah and identify the factors contributing to model performance issues. The results of this study will help support future air quality model development, policy and regulatory decisions for the oil and gas sector.