Michelle Marie Scherer | |
Alma Mater: | OGI School of Science and Engineering University of Connecticut (MS) University of Virginia (BSc) |
Thesis Title: | Equilibrium studies of chromate adsorption on glacio-fluvial aquifer sediments (MS) |
Thesis Url: | http://www.worldcat.org/oclc/30132751 |
Thesis Year: | 1994 |
Workplaces: | University of Iowa |
Website: | Scherer Laboratory |
Michelle Marie Scherer is the Donald E. Bently Professor of Engineering at the University of Iowa. Her research considers environmental geochemistry, in particular redox-reactions at mineral-water interfaces. In 2009 she was awarded the Association of Environmental Engineering and Science Professors Distinguished Service Award.
Scherer grew up in New Jersey.[1] She enjoyed mathematics and problem solving as a child, and was particularly interested in using engineering in an environmental context. She studied systems engineering at the University of Virginia.[2] She moved to the University of Connecticut where she earned a master's degree in civil and environmental engineering. Scherer joined the OGI School of Science and Engineering for her doctoral studies and earned a PhD in 1998.
In 1998 Scherer joined the University of Iowa as an Assistant Professor. She was promoted to Professor in 2010 and made a Chair in the Department of Civil and Environmental Engineering. That year she was awarded the AEESP Frontier in Research Award.[3] Scherer specialises in environmental geochemistry, in particular, the interaction of pollution and soil. Before Scherer it was believed that pollutants only interacted with the surfaces of soil and minerals, but Scherer has demonstrated that they can penetrate the interiors of mineral particles.[4]
Her research considers the reduction-oxidation reactions that occur at iron oxide surfaces.[5] She has investigated the attenuation of chlorinated solvents (including perchloroethylene, PCE, and trichloroethylene, TCE) through biological degradation, and the impact of abiotic degradation due to iron minerals in natural attenuation. She has shown that at high iron concentrations the formation of metastable mineral phases can reduce the PCE and TCE, making them more susceptible to attenuation.[6]
She is involved with a University of Iowa project to monitor the levels of lead in Iowan drinking water, which is known to impact children's physical and mental capacity.[7] Whilst the Flint water crisis occurred due to city-wide changes in water sources and poor control of corrosion, Iowan homes often have sources of lead in their own plumbing, and need lead monitoring at the tap.[8]
In 2014 she spoke about Women Leaders in Environmental Chemistry at the annual American Chemical Society meeting. She joined the United States Environmental Protection Agency Advisory Board in 2014.[9]
Her awards and honours include:
Her publications include: