Ozone over Sheboygan
The SPARC team’s data will complement NASA measurements already gathered from remote sensing instruments on an
aircraft flying in specific patterns over the area — from Zion, Illinois, to Sheboygan — and data from a NOAA research ship
equipped with EPA instruments that collected nearshore and offshore measurements. It will also add to ozone
measurements collected via automobile by EPA Region 5 and UW–Eau Claire Professor Patricia Cleary.
“Together, the aircraft, ship and land measurements will help build a more complete picture of the atmosphere,” Wagner
Additionally, EPRI has funded Scientific Aviation to provide measurements from the air along the Lake Michigan coast and
NSF has funded the University of Wisconsin, University of Iowa and University of Minnesota to conduct detailed chemical
measurements at a ground site in Zion.
The UW–Madison ground team includes Tim Bertram, professor of chemistry, and his graduate students Gordon Novak
and Michael Vermeuel. Bertram explains that ozone is commonly found in Earth’s atmosphere, where it protects surface
dwellers from harmful solar radiation, but it is usually high up and away from people. However, anthropogenic sources —
like the burning of fossil fuels — can escalate ozone production to unsafe levels, especially when it forms in cities or
densely populated areas.
Ozone is produced by incomplete combustion, which creates what are known as precursor molecules, like nitric oxide, and
volatile organic compounds. These are converted into ozone through a sunlight-dependent chemical process. Ozone levels
tend to be higher during the summer months because of increased solar intensity.
The EPA is responsible for setting ozone pollution standards nationwide and works with state agencies to monitor air
quality conditions. Cities that fail to meet certain air quality standards must undergo a planning process to outline ways of
reducing pollutants like ozone. Pierce, who has studied ozone transport for more than 20 years, says improving models will
assist the EPA and cities as they plan for future air quality needs and requirements.
“The field phase of the 2017 Lake Michigan Ozone Study has been an overwhelming success and we look forward to using
the measurements collected during the campaign to help understand why coastal ozone monitors show higher ozone
levels than inland, and improve our ability to model ozone within this complex region,” says Pierce.
This research is supported by NOAA/STAR GOES-R grant under NOAA-University of Wisconsin CIMSS Cooperative
Agreement number NA15NES4320001, U.S. Department of Commerce.
|Lake Michigan shoreline as seen from Sheboygan, Wisconsin.
University of Wisconsin–Madison Space Science and Engineering
Center (SSEC) researchers have joined an atmospheric study over
Sheboygan and other cities along the lake’s coast. Credit: SSEC
Scientists converge to study ozone, an atmospheric
mystery near Lake Michigan
By Eric Verbeten
For several years, air quality managers have identified
elevated levels of ozone in the Sheboygan, Wisconsin,
area. It remains an atmospheric mystery since high
levels of ozone are usually associated with larger cities. It
is also an issue of great concern to public health officials
because ozone is a known respiratory irritant that poses
health threats to vulnerable populations, especially the
young and the elderly, and those with breathing
problems like asthma.
In an effort to unravel the mystery and understand how
pollution moves along the western shoreline of Lake
Michigan, University of Wisconsin–Madison Space
Science and Engineering Center (SSEC) researchers
have joined an atmospheric study over Sheboygan and other cities along the lake’s coast.
The goal of the Lake Michigan Ozone Study (LMOS 2017) is to understand how wind currents can transport pollution from
one location to another — especially ozone, which poses human health risks when found near the Earth’s surface. The data
collected will also be integrated into ozone models used by air quality managers at agencies such as the Environmental
Protection Agency (EPA), the Lake Michigan Air Directors Consortium (LADCO), and the Wisconsin Department of Natural
Brad Pierce, a NOAA physical scientist
who is stationed at UW–Madison and is
leading the LMOS campaign. Credit: SSEC
“We want to help improve these models and better predict when ozone events will
happen, and in turn, protect health,” says Brad Pierce, a NOAA physical scientist
who is stationed at UW–Madison and is leading the LMOS campaign.
The study represents a $1.3 million multi-agency partnership that includes NASA,
the National Science Foundation (NSF), EPA, the National Oceanic and
Atmospheric Administration (NOAA), the Electric Power Research Institute (EPRI),
and other organizations and universities.
“The plan is to collect data that will give us a comprehensive profile of the
atmosphere along the shore of Lake Michigan,” says Tim Wagner, SSEC
Wagner oversees the research efforts for a suite of ground-based instruments,
known as the SSEC Portable Atmospheric Research Center, or SPARC. SPARC is a customized, 17-foot trailer equipped
with an array of sensitive tools used to measure the atmosphere, many of which were designed and built at SSEC. Data
gathered from the SPARC instruments at the study site will help construct a picture of the atmosphere over Sheboygan and
surrounding areas through wind and temperature measurements, and help resolve different types of particles like ice, dust
and other aerosols.
“By understanding the atmospheric structure, it gives context to the other data that are part of the whole campaign,” says
Wagner. “It’s an important piece of the puzzle to understanding what’s happening up there.”