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Overview of the Lake Michigan Ozone Study 2017

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  • 1 aUniversity of Iowa, Iowa City, IA
  • | 2 bSpace Science and Engineering Center, University of Wisconsin, Madison, WI
  • | 3 cnow at University Corporation for Atmospheric Research (UCAR), Boulder, CO
  • | 4 dLake Michigan Air Directors Consortium (LADCO), Chicago, IL
  • | 5 eNASA Langley Research Center, Hampton, VA
  • | 6 fUniversity of Minnesota, Saint Paul, MN
  • | 7 gUniversity of Wisconsin, Madison, WI
  • | 8 hUniversity of Wisconsin, Eau Claire, WI
  • | 9 iUniversity of Northern Iowa, Cedar Falls, IA
  • | 10 jWisconsin Department of Natural Resources, Madison, WI
  • | 11 kU.S. EPA Region 5, Chicago, IL
  • | 12 lPurdue University, West Lafayette, IN
  • | 13 mNASA Goddard Space Flight Center, Greenbelt, MD
  • | 14 nElectric Power Research Institute, Palo Alto, CA
  • | 15 oCenter for Environmental Measurement and Modeling, United States Environmental Protection Agency
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Abstract

The Lake Michigan Ozone Study 2017 (LMOS 2017) was a collaborative multi-agency field study targeting ozone chemistry, meteorology, and air quality observations in the southern Lake Michigan area. The primary objective of LMOS 2017 was to provide measurements to improve air quality modeling of the complex meteorological and chemical environment in the region. LMOS 2017 science questions included spatiotemporal assessment of nitrogen oxides (NOx = NO + NO2) and volatile organic compounds (VOC) emission sources and their influence on ozone episodes, the role of lake breezes, contribution of new remote sensing tools such as GeoTASO, Pandora, and TEMPO to air quality management, and evaluation of photochemical grid models. The observing strategy included GeoTASO on board the NASA UC-12 capturing NO2 and formaldehyde columns, an in situ profiling aircraft, two ground-based coastal enhanced monitoring locations, continuous NO2 columns from coastal Pandora instruments, and an instrumented research vessel. Local photochemical ozone production was observed on 2 June, 9–12 June, and 14–16 June, providing insights on the processes relevant to state and federal air quality management. The LMOS 2017 aircraft mapped significant spatial and temporal variation of NO2 emissions as well as polluted layers with rapid ozone formation occurring in a shallow layer near the Lake Michigan surface. Meteorological characteristics of the lake breeze were observed in detail and measurements of ozone, NOx, nitric acid, hydrogen peroxide, VOC, oxygenated VOC (OVOC), and fine particulate matter (PM2.5) composition were conducted. This article summarizes the study design, directs readers to the campaign data repository, and presents a summary of findings.

Corresponding author: Charles O. Stanier, charles-stanier@uiowa.edu

Abstract

The Lake Michigan Ozone Study 2017 (LMOS 2017) was a collaborative multi-agency field study targeting ozone chemistry, meteorology, and air quality observations in the southern Lake Michigan area. The primary objective of LMOS 2017 was to provide measurements to improve air quality modeling of the complex meteorological and chemical environment in the region. LMOS 2017 science questions included spatiotemporal assessment of nitrogen oxides (NOx = NO + NO2) and volatile organic compounds (VOC) emission sources and their influence on ozone episodes, the role of lake breezes, contribution of new remote sensing tools such as GeoTASO, Pandora, and TEMPO to air quality management, and evaluation of photochemical grid models. The observing strategy included GeoTASO on board the NASA UC-12 capturing NO2 and formaldehyde columns, an in situ profiling aircraft, two ground-based coastal enhanced monitoring locations, continuous NO2 columns from coastal Pandora instruments, and an instrumented research vessel. Local photochemical ozone production was observed on 2 June, 9–12 June, and 14–16 June, providing insights on the processes relevant to state and federal air quality management. The LMOS 2017 aircraft mapped significant spatial and temporal variation of NO2 emissions as well as polluted layers with rapid ozone formation occurring in a shallow layer near the Lake Michigan surface. Meteorological characteristics of the lake breeze were observed in detail and measurements of ozone, NOx, nitric acid, hydrogen peroxide, VOC, oxygenated VOC (OVOC), and fine particulate matter (PM2.5) composition were conducted. This article summarizes the study design, directs readers to the campaign data repository, and presents a summary of findings.

Corresponding author: Charles O. Stanier, charles-stanier@uiowa.edu
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