William H. Schlesinger

William H. Schlesinger (born April 30, 1950) is a biogeochemist and the retired president of the Cary Institute of Ecosystem Studies, an independent not-for-profit environmental research organization in Millbrook, New York. He assumed that position after 27 years on the faculty of Duke University, where he served as the Dean of the Nicholas School of the Environment and Earth Sciences and James B. Duke Professor of Biogeochemistry.

Education, career, and honors

Schlesinger began his college education at Dartmouth College where he received his A.B. in biology in 1972. He earned his Ph.D. at Cornell University in Ecology and Systematics in 1976.

Schlesinger’s teaching career began at the University of California, Santa Barbara where he was an assistant professor of biology for four years. Afterwards, he moved to Duke University, becoming a full professor and teaching for over 20 years. In 2001, Schlesinger was promoted as the Dean of the Nicholas School of the Environment and Earth Sciences at Duke University. Schlesinger retired as the dean on June 1, 2007, when he became the president of the Cary Institute of Ecosystem Studies.

Schlesinger was elected a member of the National Academy of Sciences in 2003 and was President of the Ecological Society of America from 2003 to 2004. He is also a fellow of the American Academy of Arts and Sciences, the American Geophysical Union, The American Association for the Advancement of Science (AAAS), The Ecological Society of America, and the Soil Science Society of America. He is a member of the Board of Trustees of the Southern Environmental Law Center, the Natural Resources Defense Council (NRDC) and the Doris Duke Charitable Foundation. Currently he also serves on the Science Advisory Board (SAB) for the Environmental Protection Agency (EPA).

Scientific Outreach

Schlesinger has testified before U.S. House and Senate Committees on the importance of habitat preservation and the impacts of air pollution and climate change on humans and the natural environment. In addition to his 200+ scientific publications, he has authored more than 100 editorials and features on environmental subjects, appearing in the Los Angeles Times, the Chicago Tribune, the Albany Times Union, and the Raleigh News and Observer.

Contributions to biogeochemistry

Schlesinger has a long research career studying the circulation of the chemical elements in natural ecosystems—now widely known as biogeochemistry. Most of his work has focused on soils, especially on the carbon stored in soils, which contain a major pool in the global carbon cycle. His early work provided estimates of the storage of organic carbon (humus) and inorganic carbon (largely calcium carbonate) in soils, losses of soil carbon to runoff, changes in soil carbon with conversion of land to agriculture, and accumulations of carbon during soil development. More recently, he has examined changes in soil processes and soil carbon storage that accompany plant growth at elevated levels of atmospheric carbon dioxide, as simulated in the Duke Forest Free-Air CO2 Enrichment (FACE) experiment. His work also evaluates recommendations for carbon sequestration as a means to control the accumulation of CO2 in Earth’s atmosphere and to mitigate the potential for global warming.

In addition to studies of soil carbon, Schlesinger has provided global budgets summarizing the sources of atmospheric ammonia, the fate of human-derived nitrogen on land, and the global boron cycle. He has shown that biology leaves its imprint on global geochemical cycles, and that earth system function cannot be fully understood without considering the impacts of biology. His approach, philosophy, and much of his other work is summarized in a textbook, Biogeochemistry: an analysis of global change in its third edition and coauthored with Emily S. Bernhardt of Duke University, available through Academic Press/Elsevier, San Diego.

Work with desert ecosystems, 1991-2006

Schlesinger served as the co-principal investigator for the Jornada Basin Long Term Ecological Research (LTER) located in the Chihuahuan Desert in southern New Mexico. Research projects mainly focus on inorganic fluxes, including studies of ammonia volatilization from soils, hydrology natural runoff plots and transect soil water content. He has also worked extensively in arid ecosystems and landscapes, studying responses to resource redistribution and global change, which can lead to soil degradation and regional desertification. Schlesinger postulated that the patchy distribution of vegetation in desert regions controls many aspects of soil fertility and the response of deserts to overgrazing and climate change.

Forest-atmosphere carbon transfer and storage, 1996-1999

Schlesinger was the co-principal investigator for the Free Air CO2 Enrichment (FACE) Experiment in the Duke Forest. The object of the study was to investigate the efficacy of carbon sequestration in forest ecosystems (vegetation and soil) in response to elevated atmospheric CO2 concentration, as a means to mitigate the potential for global warming.

During this decade-long experiment, Schlesinger and John Lichter (Bowdoin College) found only small changes in soil carbon content, suggesting that enhanced carbon storage in soils is unlikely to play a major role in slowing the growth of atmospheric CO2 and the magnitude of global climate change. Much larger changes were seen in the growth rate of trees, but even those were unlikely to sequester a significant increment of carbon worldwide as a result of rising CO2 in Earth’s atmosphere.

Work at the Cary Institute of Ecosystem Studies, 2007-2014

When he was appointed President of the Cary Institute in Millbrook, NY., Schlesinger expanded its existing science program with the hiring of three new scientists and establishing strong programs for the translation of science to the public. The Cary Institute’s Friday-Night-at-Cary Lecture series and its daily program, Earth Wise, on WAMC Northeast Public Radio were widely followed for their presentations of science for the general public.

gollark: I've gone to an extreme hills and done a lot of mining. No zinc. Sorely tempted to just spawn some.
gollark: For some stupid reason the cell back at the base seems to favour drawing from the reactor buffer above using the local power plant, which is irritating.
gollark: Also, it can do 9kRF/t (the power cabling) per connection, which is nice.
gollark: The Ten Metre Island power line is complete!
gollark: I'm going to run redstone fluxducts, which may work out cheaper since no nickel.

References

  • Schlesinger, W. H., Better Living Through Biogeochemistry, Ecology, 85(9), 2004, pp. 2402–2407
  • Schlesinger, W. H. and Bernhardt, E.S., Biogeochemistry, An Analysis of Global change, Academic Press, 3rd ed., 2013, pp. 159–163
  • Schlesinger, W. H., Lichter, J., 2001. Limited carbon storage in soil and litter of experimental forest plots under increased atmospheric CO2. Nature 411, 466-469.
  • Schlesinger, W.H. 2006. Global change ecology. Trends in Ecology and Evolution (TREE) 21: 348-351.
  • Schlesinger, W.H. 2009. On the fate of anthropogenic nitrogen. Proceedings of the National Academy of Sciences. 106:203-208
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