You are here

Climate Change and Waterborne Disease Risk in the Great Lakes Region of the U.S.

TitleClimate Change and Waterborne Disease Risk in the Great Lakes Region of the U.S.
Publication TypeManual Entry
Year of Publication2008
AuthorsPatz, Jonathan A., Stephen J. Vavrus, Christopher K. Uejio, and Sandra L. McLellan
American Journal of Preventive Medicine
Volume35
Pagination451 - 458
ISSN0749-3797
Abstract

Abstract Extremes of the hydrologic cycle will accompany global warming, causing precipitation intensity to increase, particularly in middle and high latitudes. During the twentieth century, the frequency of major storms has already increased, and the total precipitation increase over this time period has primarily come from the greater number of heavy events. The Great Lakes region is projected to experience a rise these extreme precipitation events. For southern Wisconsin, the precipitation rate of the 10 wettest days was simulated using a suite of seven global climate models from the UN Intergovernmental Panel on Climate Change (IPCC) Fourth Assessment Report. For each ranking, the precipitation rate of these very heavy events increases in the future. Overall, the models project that extreme precipitation events will become 10% to 40% stronger in southern Wisconsin, resulting in greater potential for flooding, and for the waterborne diseases that often accompany high discharge into Lake Michigan. Using 6.4 cm (2.5 in) of daily precipitation as the threshold for initiating combined sewer overflow into Lake Michigan, the frequency of these events is expected to rise by 50% to 120% by the end of this century. The combination of future thermal and hydrologic changes may affect the usability of recreational beaches. Chicago beach closures are dependent on the magnitude of recent precipitation (within the past 24 hours), lake temperature, and lake stage. Projected increases in heavy rainfall, warmer lake waters, and lowered lake levels would all be expected to contribute to beach contamination in the future. The Great Lakes serve as a drinking water source for more than 40 million people. Ongoing studies and past events illustrate a strong connection between rain events and the amount of pollutants entering the Great Lakes. Extreme precipitation under global warming projections may overwhelm the combined sewer systems and lead to overflow events that can threaten both human health and recreation in the region.

URLhttp://www.sciencedirect.com/science/article/pii/S0749379708007022
DOI10.1016/j.amepre.2008.08.026
Citation Key69

Projects

Projects that used this resource: 

Climate Impacts Tags

Impact by Sector: 
Specific Climate-Related Application: 

Planning Tags

Planning Approaches: 
Emergency Management: