May 18, 2009
Summer Haze Has A Cooling Effect
Global warming may include some periods of local cooling, according to a new study by researchers at the University of California, Berkeley. Results from satellite and ground-based sensor data show that sweltering summers can, paradoxically, lead to the temporary formation of a cooling haze in the southeastern United States.
The study, to be published the week of May 18 in the journal Proceedings of the National Academy of Sciences, found that when manmade pollutants mix with the natural compounds emitted from forests and vegetation during the hot summer months, they form secondary aerosols that reflect light from the sun. Such aerosols may also contribute to the formation of clouds, which also reflect sunlight.
The results of this study suggest that climate models need to better account for the effects of organic aerosols, the authors said.
The researchers conducted observations of aerosols throughout the earth's atmosphere using space-based satellites in combination with ground-based sunphotometers between March 2000 and February 2007.
"This is the first time a study has shown that the aerosols formed from the combination of manmade and natural emissions observed from space are relevant for understanding earth's climate," said study lead author Allen Goldstein, UC Berkeley professor and chair of the Department of Environmental Science, Policy and Management.
The study began when former UC Berkeley Ph.D. student and study co-author Charles Koven showed Goldstein satellite data that indicated a summertime spike in aerosol haze in the southeastern United States. Goldstein noticed that the increased haziness, which could not be explained by human activities alone, coincided with the known regional pattern of biogenic volatile organic compounds. The emission of these compounds - natural hydrocarbons from plants and trees - increases exponentially when the temperature rises, said Goldstein.
"These natural emissions are highly volatile, and when they react with human sources of pollution in the atmosphere, aerosols are created," said Goldstein, who also holds a joint faculty appointment in the Department of Civil and Environmental Engineering. "Nobody realized until now that enough of these aerosols were forming to influence cooling over an entire region."
The researchers estimated that the cooling effect from the aerosol haze over this region in summer is outpacing the warming effect from carbon dioxide emissions by 2-to-1 in a negative feedback system.
The results do not mean, however, that aerosols negate the effects of carbon dioxide emissions, emphasized atmospheric scientist Inez Fung, co-director of the Berkeley Institute of the Environment and a co-author of the study.
"The cooling effect of the organic aerosols we are reporting here are regional and temporal; they are dwarfed by the changes in the climate we are witnessing globally," said Fung, a UC Berkeley professor with joint appointments in the Department of Earth and Planetary Science and the Department of Environmental Science, Policy and Management. "Aerosols only remain in the atmosphere for five to 10 days, whereas carbon dioxide lingers for decades. To counter all the warming effects from greenhouse gases with aerosols, levels would have to be so high that we'd have trouble breathing, and the sky would no longer appear blue."
Study co-author Koven is now a postdoctoral fellow at the Climate and Environmental Sciences Laboratory (Laboratoire des Sciences du Climat et de l'Environnement) in France. The study was also co-authored by Colette Heald, a former UC Berkeley post-doctoral fellow who is an assistant professor of atmospheric science at Colorado State University.
The National Aeronautics and Space Administration and the National Oceanic and Atmospheric Administration helped support this study.
Written By Sarah Yang
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