UNIVERSITY PARK, Pa. — Trees, crops and other vegetation in the midwestern United States act as large carbon sinks during summer, taking in carbon dioxide (CO2) and limiting the amount of the greenhouse gas that enters the atmosphere. What happens to carbon dioxide when a cold front moves in has largely remained a mystery, but Penn State-led research is offering new insights that may help improve global carbon models.
“The focus of this research is to understand and quantify how low-pressure systems transport carbon dioxide in the atmosphere,” said Ken Davis, professor of atmospheric and climate science at Penn State. “This is part of a bigger effort, the Atmospheric Carbon and Transport-America (ACT-America) project, to learn how to interpret measurements of carbon dioxide in the atmosphere to properly infer sources and sinks of carbon dioxide at the earth surface. To do this, we need to know how carbon dioxide is mixed by the atmosphere, and there has not been much past focus on how low-pressure systems slosh around this greenhouse gas.”
Most models that deal with atmospheric carbon tend to focus on global rather than regional trends, he added, and may not properly represent the changes in atmospheric carbon dioxide that occur during these systems.
To better understand the phenomenon, the researchers studied carbon dioxide levels over Lincoln, Nebraska, before, during and after a cold front that passed through the area in August 2016. Cold fronts occur when a cold air mass pushes into a warmer air mass, and they can cause thunderstorms to form and temperatures to drop dramatically. The research team took measurements from two airplanes. The aircraft crossed the system’s frontal boundary — where the warm and cold air masses meet — multiple times. They also flew at multiple altitudes, between approximately 1,000 and 26,000 feet, and recorded the changes in carbon dioxide levels in the warm and cold sectors of the system.
The scientists entered the data into a computer model that looked at carbon dioxide levels at three different resolutions. The resolutions ranged from being nine to 1,600 times higher areal resolution than what is used in global models, giving the researchers a more precise look at what happens to carbon dioxide as the system passes. They also focused on three categories of carbon dioxide sources and sinks — biogenic fluxes, or carbon dioxide taken in and respired by plants, bacteria and animals, including humans; fossil fuel sources like cars and factories; and boundary fluxes, or in this case sources and sinks of carbon dioxide beyond the North American continent. They reported their findings in the May issue of JGR Atmospheres.
“We found a huge band of carbon dioxide trapped around the frontal system,” said Arkayan Samaddar, a doctoral candidate in the Department of Meteorology and Atmospheric Science at Penn State. The study is part of Samaddar’s doctoral dissertation. “By analyzing it at such a high resolution, we see that it’s not just one uniform band of carbon dioxide. We see a lot more structure and get more information than we would if we looked at it globally. Looking at carbon dioxide on a regional scale helps us better determine sources and sinks.”
The researchers found that during this summer front, biological sources and sinks accounted for the largest changes in atmospheric carbon dioxide, which isn’t surprising since plants, animals and humans continually take in and respire carbon dioxide and biological activity peaks in the summer, according to Davis.
“With plants you can’t readily tell the difference between photosynthesis, when they take in carbon dioxide, and respiration, when they release it. Atmospheric carbon dioxide responds to the net exchange,” Davis said.
The difference between the biogenic and fossil fuel categories, Davis added, is that the former category acts as both a source and a major sink that helps to mitigate fossil fuel emissions, whereas the fossil fuel category is a continuous source of carbon dioxide.