Reducing air pollution has important health benefits — but it can also have an unusual impact on the environment.
A new study from the National Oceanic and Atmospheric Administration (NOAA), recently published in the journal Science Advances, examined how particulate air pollution, or aerosols, and climate change have affected tropical cyclones over the past 40 years.
The results were surprising.
“Reducing air pollution does not always decrease the risk of hazards from tropical cyclones,” said Hiroyuki Murakami, a physical scientist at NOAA’s Geophysical Fluid Dynamics Laboratory and study author.
From 1980 to 2020, Europe and North America reduced particulate air pollution from automotive and energy industries. This resulted in an estimated 50 percent drop in the concentration of particulate air pollution, which has had a significant impact on water temperatures in the tropical Atlantic Ocean basin and the development of tropical cyclones, per NOAA.
“Particulate matter and water temperatures are linked, in this case, by the parasol effect,” said Dr. Boris Quennehen, lead atmospheric scientist at Plume Labs, a company acquired by AccuWeather earlier this year. Particulate matter (PM), also known as aerosols, is a mix of fine dust and tiny liquid droplets. It can come from natural sources, such as sand, wildfires, volcanic eruptions, sea salts or human activities, like fire or explosion.
“The PM parasol effect means that a part of the sunlight is reflected [or] trapped by particles and thus can’t reach the surface as it would have if particles weren’t there,” said Quennehen, who was not involved in the new study. “Less sunlight reaching the surface means less energy and thus lower temperature. Less particulate matter means less reflection, thus warmer waters.”
Warm water temperatures above 80 degrees F are one of the key ingredients in the formation of a tropical cyclone. Given the parasol effect, water temperatures in the tropical Atlantic Ocean basin are warming, creating ideal breeding grounds for tropical development.
“A warming Atlantic Ocean has been a key ingredient to a 33 percent increase in the number of tropical cyclones during this 40-year period,” said Murakami.
Moreover, there has been an increase in temperature in the middle-to-high latitudes in the Northern Hemisphere from the decreased amount of pollution, according to the study. This has resulted in a steady poleward movement of the jet stream from the tropics toward the Arctic, which has led to weaker winds in the upper troposphere in the tropical Atlantic Ocean basin.
Wind speeds gradually strengthen and sometimes change direction from the lower troposphere, which is closest to the surface of the Earth, to the upper troposphere, which is about 10 to 12 miles from the surface of the Earth in the tropical Atlantic basin. This difference between wind speed and direction and height is defined as wind shear.
The weaker winds in the upper troposphere led to an environment with little to no wind shear, which is another key ingredient in tropical cyclone development.
Low wind shear and warm ocean waters are two of the three main ingredients needed to form and sustain a tropical cyclone. The decreased air pollution from North America and Europe over the past 40 years has led to an environment in which these ingredients can flourish, the study said.
On the other side of the world, in the western North Pacific, where strong tropical cyclones are referred to as typhoons, the opposite is occurring. The increase in air pollution in the western North Pacific has been one of several factors that has contributed to a 14 percent decrease in tropical cyclones during the past 40 years, according to the study. Some other factors include natural variability and increased greenhouse gasses.
In East Asia, the increased amount of air pollution has made the land temperature cooler, which has reduced the contrast between the land and ocean temperatures. Without this contrast, the monsoon winds become weaker.
A monsoon is defined as the change in wind direction that can trigger persistent rainfall or long-duration dry weather. In the summer, the westerly Indian monsoon winds converge with trade winds in the western Pacific Ocean, creating tropical cyclones. However, with weaker monsoon winds, a lower number of tropical cyclones have formed over the last four decades, according to Murakami’s research.
Over the 40-year period Murakami examined, there has been a 40 percent increase in the amount of pollution filling the air over the western North Pacific, which has corresponded to a 14 percent decrease in the formation of tropical cyclones, or typhoons.
Without considering other factors, it might seem that adding more particles, or air pollution, to the atmosphere will help reduce the number of tropical cyclones, but such a concept is not practical, said Quennehen.
“Adding more particles in the atmosphere is not a viable solution for the Earth and humankind,” said Quennehen. “More particles means more heath impacts but also ocean acidification, which may lead to the extinction of many marine species.”
“This study indicates that decreasing air pollution leads to an increased risk of tropical cyclones, which is happening in the North Atlantic, and could also happen, if air pollution is rapidly reduced, in Asia,” said Murakami. “The ironic result suggests the necessity of careful policy decision-making in the future that considers the pros and cons of the multiple impacts.”
In the next decade, Murakami predicts increased greenhouse gases will significantly influence tropical cyclones, compared to human-caused particulate air pollution.
Produced in association with AccuWeather.com
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