Adaptive Management for Improved Water Quality in Multi-Use WatershedsEPA Grant Number: CR830653
Title: Adaptive Management for Improved Water Quality in Multi-Use Watersheds
Investigators: Lehman, John
Institution: University of Michigan
EPA Project Officer: Hiscock, Michael
Project Period: January 1, 2003 through January 1, 2006 (Extended to January 31, 2007)
Project Amount: $745,883
RFA: Nutrient Science for Improved Watershed Management (2002) RFA Text | Recipients Lists
Research Category: Water , Water and Watersheds
This project will develop a management plan for eliminating nuisance algal blooms in a chain of reservoirs along the Huron River in southeastern Michigan. The river-reservoir system is used for municipal drinking water, wastewater disposal, irrigation, industrial processes, hydroelectric generation, sport fishing, and recreation. The impoundments episodically develop surface scums of bluegreen algae, and emit foul odors including hydrogen sulfide. The project is highly relevant to local, regional, and State efforts that have been trying for years to improve water quality in this watershed. Partnerships have been formed to ensure that the scientific information gained through this project become translated into education, outreach, policy, and decision-making. Past management strategy has focused on phosphorus loading alone, but it has failed to prevent massive nuisance conditions as recently as summer 2001. Efforts based on new thinking successfully predicted the 2001 blooms; now this study will sharpen the predictions and develop management approaches to eliminate nuisance conditions in the future.
Project objectives include compartmentalizing the river system to pinpoint watershed segments responsible for inputs and internal processes that reduce stoichiometric ratios of nitrogen to phosphorus. Evaluating the role of redox transformations and assessing magnitudes of anaerobic nitrate respiration are key elements of the research plan. The project will evaluate interactions of river discharge volumes, internal transformations, and weather events as components of adaptive management theory. It will identify the places and conditions that account for significant amounts of denitrification, as well as reservoir management responses that can counteract the conditions that promote nuisance blooms.
The project emphasizes both a firm scientific foundation and translation of scientific knowledge into outreach, education, and policy development. Partnerships have been formed with municipal governments and NGOs to seek community input, disseminate information, and evaluate outreach activities. Scientific investigations will focus on nitrogen, phosphorus, trace metals, redox chemistry and hydrodynamic interactions with weather events and hydroelectric dam operations.
Successful management practices developed with cooperation from municipalities and community governments will be communicated through a well-developed outreach program. These best practices have application to similar problems in other watersheds.