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Tidal Circulation in a Sinuous Coastal Plain Estuary H. Seim, UNC-CH J. Blanton, S. Elston, SkIO Tidal propagation – interaction with the shelf Residual.

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Presentation on theme: "Tidal Circulation in a Sinuous Coastal Plain Estuary H. Seim, UNC-CH J. Blanton, S. Elston, SkIO Tidal propagation – interaction with the shelf Residual."— Presentation transcript:

1 Tidal Circulation in a Sinuous Coastal Plain Estuary H. Seim, UNC-CH J. Blanton, S. Elston, SkIO Tidal propagation – interaction with the shelf Residual circulation Overtides

2 Barotropic tides: should be straightforward… Finite Element 2D (ADCIRC) Time-dependent Fully Nonlinear Elev. BCs from Global FES95D Performs well except in SAB (B. Blanton, R. Luettich)

3 Finite Element Nonlinear 2D (ADCIRC) Western North Atl. Crossshelf Amplification Equatorward phase propagation Latest phase along GA/FL border Shelf response sensitive NC SC FL GA M 2 Elevation without estuaries – tide experiences two-fold amplitude increase and notable phase change m (B. Blanton)

4 Problem: typical coastal tide station is not “in” the typical shelf model domain Fort Pulaski, GA Landward Bndy of Operational models (B. Blanton)

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6 In the SAB large sections of the coastline are backed by extensive estuaries (K. Smith, D. Lynch) depth (m)

7 M 2 Solution Elevation Difference Amplitude Ratio Est sol’n Amp -------------------------- > 1 NoEst sol’n Amp Phase Diff (in red) Est Phase - NoEst Phase >0 (B. Blanton)

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9 Including estuaries increases dissipation >25%... Strange result – inclusion of highly dissipative estuaries leads to 10% increase in tidal range. Log 10 W/m 2 Longitude Latitude (B. Blanton)

10 Satilla River 1 m tide 2-4 m mean depth 50 m 3 /s avg riverflow 0.5-1 m/s tidal currents Pristine, typically 2 channel 5 km MHHW width, 1km MLW width

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20 Depth-scaling accounts for ~25% of variance – rest due to non-linearities?

21 M2 phase – earlier in shallow channels, remarkable changes at triple junction

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28 M 2 +M 4 fit reasonable on neap, arger residuals on spring tides

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30 Conclusions Damping of propagation appears weak – need to do some simple modeling Tidal residual flows strong, structure reminiscent of headland eddies Sub-basin exhibits much different behavior Overtide generation complex, varies spatially and with time.

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