Evaluation of WRF-Chem air quality forecasts during the AEROMMA and STAQS 2023 field campaigns

• Published in: Journal of the Air & Waste Management Association (1995) Vol. 74; no. 11; pp. 783 - 803
• Main Authors: Acdan, Juanito Jerrold Mariano, Pierce, R. Bradley, Kuang, Shi, McKinney, Todd, Stevenson, Darby, Newchurch, Michael J., Pfister, Gabriele, Ma, Siqi, Tong, Daniel
• Format: Journal Article
• Language: English
• Published: United States Taylor & Francis 01.11.2024; Taylor & Francis Ltd
• Subjects: Aerosols; Air pollution; Air quality; Air quality measurements; Atmospheric chemistry; Atmospheric composition; Chemical composition; Damage assessment; Errors; Flight planning; Forecasting; GOES satellites; Lakes; Lead time; Lidar; Marine chemistry; Marine environment; Megacities; Optical analysis; Optical thickness; Outdoor air quality; Ozone; Particulate emissions; Particulate matter; Plumes; Pollution; Real time; Rural areas; Smoke; Time measurement; Weather forecasting; Wildfires; Wind measurement; Wind speed; United States > US; Chicago Illinois
• ISSN: 1096-2247; 2162-2906; 2162-2906
• DOI: 10.1080/10962247.2024.2380333

A real-time air quality forecasting system was developed using the Weather Research and Forecasting model coupled with Chemistry (WRF-Chem) to provide support for flight planning activities during the NOAA Atmospheric Emissions and Reactions Observed from Megacities to Marine Areas (AEROMMA) and NASA Synergistic TEMPO Air Quality Science (STAQS) 2023 field campaigns. The forecasting system operated on two separate domains centered on Chicago, IL, and New York City, NY, and provided 72-hour predictions of atmospheric composition, aerosols, and clouds. This study evaluates the Chicago-centered forecasting system's 1-, 2-, and 3-day ozone (O 3 ) forecast skill for Chiwaukee Prairie, WI, a rural area downwind of Chicago that often experiences high levels of O 3 pollution. Comparisons to vertical O 3 profiles collected by a Tropospheric Ozone Lidar Network (TOLNet) instrument revealed that forecast skill decreases as forecast lead time increases. When compared to surface measurements, the forecasting system tended to underestimate O 3 concentrations on high O 3 days and overestimate on low O 3 days at Chiwaukee Prairie regardless of forecast lead time. Using July 25, 2023, as a case study, analyses show that the forecasts underestimated peak O 3 levels at Chiwaukee Prairie during this regionwide bad air quality day. Wind speed and direction data indicates that this underestimation can partially be attributed to lake breeze simulation errors. Surface fine particulate matter (PM 2.5 ) measurements, Geostationary Operational Environmental Satellite-16 (GOES-16) aerosol optical depth (AOD) data, and back trajectories from the NOAA Hybrid Single-Particle Lagrangian Integrated Trajectory (HYSPLIT) model show that transported Canadian wildfire smoke impacted the Lake Michigan region on this day. Errors in the forecasted chemical composition and transport of the smoke plumes also contributed to underpredictions of O 3 levels at Chiwaukee Prairie on July 25, 2023. The results of this work help identify improvements that can be made for future iterations of the WRF-Chem forecasting system. Implications: Air quality forecasting is an important tool that can be used to inform the public about upcoming high pollution days so that individuals may plan accordingly to limit their exposure to health-damaging air pollutants. Forecasting also helps scientists make decisions about where to make observations during air quality field campaigns. A variety of observational datasets were used to evaluate the accuracy of an air quality forecasting system that was developed for NOAA and NASA field campaigns that occurred in the summer of 2023. These evaluations inform areas of improvement for future development of this air quality forecasting system.