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Modeling of the Cape Fear River Estuary plume

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Abstract

The Environmental Fluid Dynamic Code, an estuarine and coastal ocean circulation model, is used to simulate the distribution of the salinity plume in the vicinity of the mouth of the Cape Fear River Estuary, North Carolina. The individual and coupled effects of the astronomical tides, river discharge, and atmospheric winds on the spatial and temporal distributions of coastal water levels and the salinity plume were investigated. These modeled effects were compared with water level observations made by the National Oceanic and Atmospheric Administration and salinity surveys conducted by the Coastal Ocean Research and Monitoring Program. Model results and observations of salinity distributions and coastal water level showed good agreement. The simulations indicate that strong winds tend to reduce the surface plume size and distort the bulge shape near the estuary mouth due to enhanced wind-induced surface mixing. Under normal discharge conditions, tides, and light winds, the southward outwelling plume veers west. Relatively moderate winds can mechanically reverse the flow direction of the plume. Under conditions of weak to moderate winds the water column does not mix vertically to the bottom, while in strong wind cases the plume becomes vertically well mixed. Under conditions of high river discharge the plume increases in size and reaches the bottom. Vertical mixing induced by strong spring tides can also enable the plume to reach the bottom.

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Authors and Affiliations

  1. Department of Marine, Earth and Atmospheric Sciences, North Carolina State University, P. O. Box 8208, 27695, Raleigh, North Carolina

    Meng Xia & Lian Xie

  2. College of Physical and Mathematical Sciences, North Carolina State University, P. O. Box 8208, 27695, Raleigh, North Carolina

    Leonard J. Pietrafesa

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  1. Meng Xia
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  2. Lian Xie
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  3. Leonard J. Pietrafesa
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Correspondence to Meng Xia.

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Xia, M., Xie, L. & Pietrafesa, L.J. Modeling of the Cape Fear River Estuary plume. Estuaries and Coasts: J ERF 30, 698–709 (2007). https://doi.org/10.1007/BF02841966

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  • DOI: https://doi.org/10.1007/BF02841966

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