Eliminating air pollution emissions from energy-related activities in the United States would prevent more than 50,000 premature deaths each year and provide more than $600 billion in benefits each year from avoided illness and death, according to a new study by University of Wisconsin-Madison researchers.
Published today in the journal GeoHealth, the study reports the health benefits of removing dangerous fine particulates released into the air by electricity generation, transportation, industrial activities and building functions like heating and cooking — also major sources of carbon dioxide emissions that cause climate change, since they predominantly rely on burning fossil fuels like coal, oil, and natural gas.
“Our work provides a sense of the scale of the air quality health benefits that could accompany deep decarbonization of the U.S. energy system,” says Nick Mailloux, lead author of the study and a graduate student at the Center for Sustainability and the Global Environment in UW-Madison’s Nelson Institute for Environmental Studies. “Shifting to clean energy sources can provide enormous benefit for public health in the near term while mitigating climate change in the longer term.”
Working with scientists specializing in air quality and public health, Mailloux used a model from the U.S. Environmental Protection Agency to determine the health benefits from a complete reduction in emissions of fine particulate matter and of sulfur dioxide and nitrogen oxides. These compounds can form particulate matter once released into the atmosphere.
These pollutants contribute to health problems such as heart disease, stroke, chronic obstructive pulmonary disease, lung cancer and lower respiratory infections that can dramatically shorten lifespans. Doing away with these pollutants would save about 53,200 lives each year in the US, providing about $608 billion in benefits from avoided healthcare costs and loss of life, according to the researchers’ analysis.
The researchers also studied the health effects if regions of the country were to act independently to reduce emissions instead of as part of a concerted nationwide effort. The effects can differ widely in different parts of the US because of regional variations in energy use and population.
The Southwest, a region comprising Arizona, California and Nevada, would retain 95 percent of the benefits if it moved alone to eliminate fine particle emissions.
“In the Mountain region, though, most of the benefit of emissions removal is felt somewhere else,” Mailloux says. “Just 32 percent of the benefit remains in states in the Mountain region. This is partly because there are large population centers downwind of the Mountain region that would also benefit.”
Every region of the country sees more benefit from nationwide action than from acting on their own to reduce emissions.
“The Great Plains, for example, gets more than twice as much benefit from nationwide efforts as it does from acting alone,” says Mailloux. “The more that states and regions can coordinate their emissions reductions efforts, the greater the benefit they can provide to us all.”
The researchers hope that by describing the near-term payoffs on top of the threats of more distant climate impacts, the new study motivates more action on climate change.
“Our analysis is timely, following last month’s report from the UN Intergovernmental Panel on Climate Change that called for urgent action to transform the world’s energy economy,” says Jonathan Patz, senior author of the study and a UW-Madison professor in the Nelson Institute and Department of Population Health Sciences. “My hope is that our research findings might spur decision-makers grappling with the necessary move away from fossil fuels, to shift their thinking from burdens to benefits.”
Publication Referenced in the Article:
Nicholas A. Mailloux, David W. Abel, Tracey Holloway, Jonathan A. Patz. Nationwide and Regional PM 2.5 ‐Related Air Quality Health Benefits From the Removal of Energy‐Related Emissions in the United States. GeoHealth, 2022; 6 (5) DOI: 10.1029/2022GH000603
This article was written by the team at the University of Wisconsin-Madison.