Despite overall lower levels of harmful emissions from power plants and vehicles throughout the year, winter air pollution in the Eastern United States remains high. A new study explains why.
Summer used to be the poster child for haze-containing particles that cause asthma, lung cancer, and other illnesses, researchers say.
“In the past 10 years or so, the summer air pollution levels have decreased rapidly, whereas the winter air pollution levels have not. Air quality in summer is now almost the same as in winter in the eastern US,” says corresponding author Viral Shah, who did the work as part of his doctorate in atmospheric sciences at the University of Washington. “We have pinpointed the chemical processes that explain the seasonal difference in response to emissions reductions.”
The study, which appears in the Proceedings of the National Academy of Sciences, shows that the particles follow different pathways in the winter.
Smog ‘flavors’
Results came from analyzing observations collected during the 2015 Wintertime Investigation of Transport, Emissions and Reactivity (WINTER) campaign. During that effort, researchers spent six weeks in winter flying through pollution plumes over New York City, Baltimore, Cincinnati, Columbus, Pittsburgh, Washington, DC, and along the coal-fired power plants of the Ohio River Valley.
“We now have a better tool to look at what is the best strategy to improve wintertime air quality…”
Particles that form smog come in different flavors. Two important ones are sulfates, from sulfur dioxide emitted mainly by coal-fired power plants, and nitrates, created from nitrogen oxides known collectively as NOx. Air-quality regulations have lowered sulfur dioxide in the US by 68 percent between 2007 and 2015, and NOx by about a third during that time.
Summertime levels of particulates—when the two flavors of oxides clump up into watery packets of nitrates and sulfates that create beautiful sunsets but harm human health—have dropped in the eastern US by about a third during that time. But the winter concentrations of particulates have decreased by only half as much, for reasons that had been unclear.
“The air quality models that we use to understand the origin of air pollution perform quite well in summer, but have some issues in the wintertime. Before this study, we could not reproduce the observed particulate composition in winter,” says Lyatt Jaeglé, who was the paper’s second author and co-principal investigator of the field campaign.
“We now have a better tool to look at what is the best strategy to improve wintertime air quality on regional scales in the eastern US, and potentially other places, like Europe and Asia.”
Winter air chemistry
In the summer, some of the emitted NOx and sulfur dioxide remains in the gas phase and gets zapped by sunlight or deposited on land, and the rest forms particulates in the form of nitrates and sulfates. As the primary ingredients drop, so do the levels of particulates.
But the new analysis shows that the chemistry of wintertime air follows a more complex path. With less sunlight and colder temperatures, more of the chemistry happens in the liquid phase, on the surfaces of existing particulates or liquid and ice clouds. In that phase, as the primary ingredients drop, the efficiency of converting sulfur dioxide to sulfate rises, because more oxidants are available. And as sulfate goes down, the particulates become less acidic, making NOx convert more easily to nitrates.
So, even though air quality regulations have reduced both types of primary emissions, the total amount of particulates that harm human health has dropped more slowly.
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“It’s not that the reductions aren’t working. It’s just that the reductions have a cancelling effect, and the cancelling effect has a set strength,” says Shah, who is now a postdoctoral researcher at Harvard University. “We need to make further reductions. Once the reductions become larger than the cancelling effect, then winter will start behaving more like summer.”
How will air quality change?
The study predicts that unless emissions reductions outpace current forecasts, air quality in winter will continue to improve only gradually until at least 2023. At this rate it would be several years before emissions reach levels when wintertime pollution starts to drop more quickly.
“This paper shows that understanding the underlying atmospheric chemistry that converts primary pollutants into fine particulate matter is critical for calibrating our expectations about what emissions reductions will accomplish, and therefore for how to optimize future emissions reductions to continue getting the ‘biggest bang for the buck’ in terms of reducing fine particulate matter concentrations,” says third author Joel Thornton, who was the principal investigator on the field campaign.
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The findings suggest that more emissions reductions, of both sulfur and nitrogen oxides, will be needed to improve wintertime air quality in the Eastern US and other cold climates.
“This research helps explain why emissions controls to reduce air pollution substances, such as sulfate and nitrate, have not been as successful as expected in the eastern US in winter,” says Sylvia Edgerton, program director in the National Science Foundation’s Division of Atmospheric and Geospace Sciences, which funded the research.
“The WINTER field campaign produced a unique set of winter observations. They demonstrate that chemical feedbacks during winter months counteract expected reductions in air pollution due to reduced emissions.”
Additional coauthors are from the University of Washington; Georgia Tech; the University of Colorado Boulder; Colorado State University; North Carolina A&T State University; the National Center for Atmospheric Research in Boulder; and the National Oceanic and Atmospheric Administration in Boulder. The National Science Foundation, with in-kind support from NASA and the National Oceanic and Atmospheric Administration, funded the work.
Source: University of Washington