A Numerical Model Study of the Effect of Channel Deepening on Shoaling and Salinity Intrusion in the Savannah Estuary

Abstract

A numerical laterally averaged estuary model has been modified to handle sediment along with flow, temperature, and salinity computations. A bed model that allows for multiple layer when the sediment is cohesive has been incorporated to simulate the exchange of sediment between the bed and the water column. The resulting model, called LAEMSED, is useful in assessing the impact of changes in channel geometry on salinity instrusion and shoaling in either a single channel or a multiple-connected system of channels. Results from a study in the Savannah Estuary show good agreement with 1985 field data on tides, velocities, and salinities. Good agreement with shoaling rates estimated from dredging records was also obtained. Results from applications of the verified model to assess the impact on salinity intrusion and shoaling of deepening the navigation channel by 3 and 6 ft are presented. General conclusions are that deepening the navigation channel as much as 6 ft moves the primary shoaling region upstream about 10 miles to the river reach containing the Kings Island Turning Basin with an overall increase in shoaling volume of about 14%. For the same increase in depth, salinities along Front River will increase by a maximum of 2-4 ppt, depending upon tidal and freshwater inflow conditions, whereas the maximum increase in salinity near the wildlife refuge on Little Back River will be less than 1.0 ppt. Sediment transport.

Document Details

Document Type

Technical Report

Publication Date

Dec 01, 1989

Accession Number

ADA217107

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