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Brian L. Howes and Dale D. Goehringer, Woods Hole Oceanographic Institution This Sea Grant-supported study is designed to encompass all of the major ecological processes dominating the water quality and productivity of a coastal system, Nantucket Harbor: nutrient conditions, high frequency oxygen monitoring, groundwater inputs, sediment nutrient regeneration, circulation, submerged macrophyte production, and fish, shellfish and infaunal populations. By choosing Nantucket Harbor as the study site--a healthy system which has only recently begun to show signs of nutrient-related stress in some of its associated, smaller water bodies--researchers will have a basis for comparison to the many studies that look at already eutrophied waters. Also, this study represents a new approach to coastal water quality management in that it seeks to manage coastal waters at the ecosystem level, and is designed to represent a model upon which management plans for other coastal communities can be based. Boundary Mixing in Massachusetts Bay Wayne R. (Rocky) Geyer and James R. Ledwell, Woods Hole Oceanographic Institution As a follow-up to a 19921994 Sea Grant-supported study, investigators will:
Benthic Processing of Sewage Additions: Controls of Denitrification in High Energy Environments Anne E. Giblin and Charles S. Hopkinson, Jr., Ecosystems Center, Marine Biological Laboratory Another continuing project taking place in Massachusetts Bay related to the multi-million dollar Boston Harbor sewage outfall project, this study investigates the importance of benthic processing of sewage inputs into coastal waters. By looking at and comparing benthic environments with fine grained and coarse grained sediments--the latter considered a higher energy environment due to more intense mixing and flushing--the project will yield information such as whether different treatment options are more appropriate in some sedimentary environments than others. These results will be of use to coastal communities involved in developing nutrient loading bylaws. In addition, the project will provide information on the basic controls of benthic nutrient regeneration that are essential for further development of a linked hydrodynamic and water quality model for Massachusetts Bay. Tidal Flat Deposition: Processes and Rheology David G. Aubrey, Woods Hole Oceanographic Institution Pollutants are known to accumulate with fine sediments along the coastal zone, within estuaries, in lagoons and along the open coast. The fate of some of these pollutants follows the fate of these fine sediments. Unfortunately, our present ability to predict transport of fine sediments, and therefore certain pollutants, is unsatisfactory. To remedy this problem, researchers will develop a consistent theoretical methodology to examine fine sediment deposition in tidal flats, areas that commonly surround heavily polluted harbors. The approach is to combine divergent methodologies of hydrodynamic modeling (tidal propagation and nonlinear interaction) with improved models of rheology and accurate field observations. Last updated: November 6, 2012 | |||||||||||||
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