Ozone pollution across the continental United States will become far more difficult to keep in check as temperatures rise, according to new research results.
The study shows that Americans face the risk of a 70 percent increase in unhealthy summertime ozone levels by 2050.
The results appear online in a paper in the Journal of Geophysical Research-Atmospheres, published by the American Geophysical Union.
The work was funded by the National Science Foundation (NSF) and the U.S. Department of Energy.
Warmer temperatures and other changes in the atmosphere related to a changing climate, including higher atmospheric levels of methane, spur chemical reactions that increase overall levels of ozone.
Unlike ozone in the stratosphere, which benefits life on Earth by blocking ultraviolet radiation from the sun, ground-level ozone can trigger a number of health problems.
Even short periods of unhealthy ozone levels can cause local death rates to rise. Ozone pollution also damages crops and other plants.
Unless emissions of specific pollutants associated with the formation of ozone are sharply cut, most of the continental United States will experience more summer days with unhealthy air by 2050, the research shows.
Heavily polluted locations in parts of the East, Midwest and West Coast, in which ozone already frequently exceeds recommended levels, could face unhealthy summer air in most years.
"It doesn't matter where you are in the United States, climate change has the potential to make your air worse," said National Center for Atmospheric Research (NCAR) scientist Gabriele Pfister, lead scientist on the study.
In addition to NCAR, the paper co-authors are from the Pacific Northwest National Laboratory; University of Colorado, Boulder; and North-West University in South Africa.
"A warming planet doesn't just mean rising temperatures, it also means risking more summertime pollution and the health effects that come with it," said Pfister.
However, the research also showed that a sharp reduction in the emissions of certain pollutants would lead to dramatically decreased levels of ozone even as temperatures warm.
The research is one of the first of its type to be conducted with new, highly advanced geoscience supercomputing capabilities.
"Understanding future changes in surface ozone over the summer has tremendous implications for air quality and human health," said Anjuli Bamzai, a program director in NSF's Division of Atmospheric and Geospace Sciences, which funded the research through NSF's Decadal and Regional Climate Prediction using Earth System Models (EaSM) Program.
"Through a series of 'what if' simulations," said Bamzai, "atmospheric chemists, climate modelers, regional modelers and developers of emissions scenarios demonstrate that a balance of emission controls can counteract the increases in future temperatures, emissions and solar radiation that in turn lead to decreases in surface ozone."
Ozone and heat
Ozone pollution is not emitted directly. It forms as a result of chemical reactions that take place between nitrogen oxides and volatile organic compounds in the presence of sunlight.
These gases come from human activities such as combustion of coal and oil, as well as natural sources such as emissions from plants.
To examine the effects of climate change on ozone pollution, Pfister and colleagues looked at two scenarios.
In one, emissions of nitrogen oxides and volatile organic compounds from human activities would continue at current levels through 2050.
In the other, emissions would be cut by 60-70 percent. Both scenarios assumed continued greenhouse gas emissions with significant warming.
The researchers found that, if emissions continue at present-day rates, the number of eight-hour periods in which ozone would exceed 75 parts per billion (ppb) would jump by 70 percent on average across the United States by 2050.
The 75 ppb level over eight hours is the threshold that is considered unhealthy by the U.S. Environmental Protection Agency. (The agency is considering tightening the standard to a value between 65 and 70 ppb over eight hours.)
Overall, the study found that, 90 percent of the time, ozone levels would range from 30 to 87 ppb in 2050 compared with an estimated 31 to 79 ppb at present.
Although the range itself shifts only slightly, the result is a much larger number of days above the threshold considered unhealthy.
There are three primary reasons for the increase in ozone with climate change:
- Chemical reactions in the atmosphere that produce ozone occur more rapidly at higher temperatures.
- Plants emit more volatile organic compounds at higher temperatures, which can increase ozone formation if mixed with pollutants from human sources.
- Methane, which is increasing in the atmosphere, contributes to increased ozone globally and will enhance baseline levels of surface ozone across the United States.
In the second scenario, Pfister and colleagues found that sharp reductions in nitrogen oxides and volatile organic compounds could reduce ozone pollution even as the climate warms.
In fact, 90 percent of the time, ozone levels would range from 27 to 55 ppb.
The number of instances when ozone pollution would exceed the 75 ppb level dropped to less than 1 percent of current cases.
"Our work confirms that reducing emissions of ozone precursors would have an enormous effect on the air we all breathe," Pfister said.
Pfister and a nationwide scientific team expect to learn more about the sources, chemistry and movement of air pollutants this summer when they launch a major field experiment known as FRAPPÉ along Colorado's Front Range.
The role of supercomputing
The study was among the first conducted on the new 1.5 petaflops Yellowstone supercomputer. The IBM system, operated by NCAR and supported by funding from NSF and the University of Wyoming, is one of the world's most powerful computers dedicated to research in the atmospheric and related sciences.
"High resolution models can consume significant time and resources on massive computers, but as shown in this research, they're often required for accurate regional ozone projections," said Irene Qualters, division director for Advanced Computing Infrastructure at NSF.
"Running these models wouldn't have been possible without the parallel processing power of the Yellowstone supercomputer, a critical part of NSF's cyberinfrastructure.
"The work will also help other researchers in related climate topics determine scenarios where coarse resolution is sufficient and, conversely, where high resolution is needed."
Thanks to its computing power, the scientists were able to simulate pollution levels hour-by-hour for 39 hypothetical summers.
This allowed the team to account for year-to-year variations in meteorological conditions, such as hot and dry vs. cool and wet, thereby getting a more detailed and statistically significant picture of future pollution levels.
To simulate the interplay of global climate with regional pollution conditions, the scientists turned to two of the world's leading atmospheric models, both based at NCAR and developed through collaborations in the atmospheric sciences community.
They used the Community Earth System Model, funded primarily by the U.S. Department of Energy and NSF, to simulate global climate as well as atmospheric chemistry conditions.
They also used an air chemistry version of the multiagency Weather Research and Forecasting Model to obtain a more detailed picture of regional ozone levels.
Even with Yellowstone's advanced computing speed, it took months to complete the complex simulations.
"This research would not have been possible even just a couple of years ago," said Pfister.
"Without the new computing power made possible by Yellowstone, you cannot depict the necessary detail of future changes in air chemistry over small areas, including the urban centers where most Americans live."