UAlbany Scientist Seeking to Measure the Effects of Aerosols on Climate Change
ASRC's Qilong Min works on innovative ways to measure how atmospheric aerosols from desert dust play a key role in climate change. (Photo by Mark Schmidt)
ALBANY, N.Y. (February 13, 2012) -- Qilong Min, Ph.D., Senior Research Associate and Professor with the Atmospheric Sciences Research Center (ASRC) at the University at Albany is developing innovative ways to measure how dust in the Sahara Desert can change clouds in the tropical Atlantic, the Caribbean region and Europe. This research will help scientists find better ways to estimate the impact dust has on climate change.
The National Science Foundation (NSF) awarded Min a three-year $399,900 grant to investigate how aerosol affects cloud systems. While many factors are at play, most cannot be accurately measured except by satellite.
Atmospheric aerosols play an important role in the climate. Aerosol is a colloid suspension of fine, solid particles in the air reflecting sunlight and producing cloud droplets. Additional aerosols would therefore brighten clouds and extend their lifetime. Mineral dust is one of four major sources of aerosols:
The burning of living and dead vegetation, or biomass burning, and
Anthropogenic air pollution, such as smoke and ash.
“Our observational study found the evidence of abundant cloud ice particles in the dust-impacted clouds,” said Min. “The effects of the dust aerosols shift the precipitation hydrometeor size from large to small, ultimately suppressing precipitation.”
Min’s research involves more accurate ways of measuring and modeling the cloud impacts of dust aerosols to help scientists predict the response of Earth’s climate to greenhouse gases.
Min earned a Ph.D. at the University of Alaska, Fairbanks, and joined the ASRC in 1994. Much of his research addresses the problems of atmospheric physics, ranging from the ionosphere to the earth´s surface, using numerical models and active and passive remote sensing from multiple platforms (satellite, airborne, and surface-based).
“We have developed an innovative analysis technique by integrating satellite and in-situ data from multiple instruments and platforms, and we also developed an advanced cloud-resolving model to simulate how mineral dust affects the development of tropical deep convective cloud systems,” said Min.
According to James Schwab, senior research associate at ASRC, African dust aerosols have been shown to be an important factor in the formation of tropical storms and hurricanes in the Atlantic.
“The transport and deposition of dust from one region to another has a variety of effects on the ecosystems involved. We have learned much about dust and its global effects on the environment in the past decade. Dr. Min’s research will certainly add to that knowledge,” Schwab said.