His research appears in the May 2004 Geochemistry, Geophysics, Geosystems (G3), an electronic journal published by the American Geophysical Union, which showcases discoveries in geophysics and geochemistry that cross traditional disciplinary boundaries and approach the Earth as a system.
Harrison's research says that CO2 fertilization may be slowing down the expected accumulation of carbon dioxide in the atmosphere by increasing carbon accumulation in terrestrial vegetation and soil.
"I have determined a CO2 fertilization factor of 1.18 for a white oak ecosystem using soil carbon and radiocarbon measurements. If major terrestrial ecosystems have similar values, CO2 fertilization may be transferring enough carbon from the atmosphere to the soil to balance the global carbon budget," according to Harrison.
"It is my hope that these concepts will be used by global change geochemists worldwide," writes Harrison. Samples for the study were collected from a white oak experiment at the Global Change Field Research Site in Oak Ridge, Tenn. The research has been funded by the U.S. Department of Agriculture.
Harrison's research focuses on the effects of fossil fuel combustion, dust and deforestation on the buildup of carbon dioxide in the atmosphere. At Boston College, he teaches courses on "Biogeochemistry of the Habitable Planet"; "Environmental Geochemistry: Living Dangerously," and "Global Warming." He earned a bachelor of science degree in chemistry at Brown University. He received a master's degree in marine chemistry from the University of California at San Diego's Scripps Institution of Oceanography, and master's and doctoral degrees in geological sciences from Columbia University.