The spatial-temporal variability of air-sea momentum fluxes observed at a tidal inlet

The spatial-temporal variability of air-sea momentum fluxes observed at a tidal inlet

Coastal waters are an aerodynamically unique environment that has been little explored from an air‐sea interaction point of view. Consequently, most studies must assume that open ocean‐derived parameterizations of the air‐sea momentum flux are representative of the nearshore wind forcing. Observatio...

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Bibliographic Details
Published in:Journal of geophysical research. Oceans Vol. 120; no. 2; pp. 660 - 676
Main Authors: Ortiz-Suslow, D. G., Haus, B. K., Williams, N. J., Laxague, N. J. M., Reniers, A. J. H. M., Graber, H. C.
Format: Journal Article
Language:English
Published: Washington Blackwell Publishing Ltd 01-02-2015
Subjects:
air-sea interaction
coastal processes
Coastal water
Coastal waters
currents
Drag coefficients
Fluxes
Geophysics
Inlets
Oceans
Parametrization
Shallow water
Simulation
Stress
Stresses
surf-zone
Tidal inlets
waves
Wind
Wind speed
wind stress
ANW, USA, North Carolina
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Summary:Coastal waters are an aerodynamically unique environment that has been little explored from an air‐sea interaction point of view. Consequently, most studies must assume that open ocean‐derived parameterizations of the air‐sea momentum flux are representative of the nearshore wind forcing. Observations made at the New River Inlet in North Carolina, during the Riverine and Estuarine Transport experiment (RIVET), were used to evaluate the suitability of wind speed‐dependent, wind stress parameterizations in coastal waters. As part of the field campaign, a small, agile research vessel was deployed to make high‐resolution wind velocity measurements in and around the tidal inlet. The eddy covariance method was employed to recover direct estimates of the 10 m neutral atmospheric drag coefficient from the three‐dimensional winds. Observations of wind stress angle, near‐surface currents, and heat flux were used to analyze the cross‐shore variability of wind stress steering off the mean wind azimuth. In general, for onshore winds above 5 m/s, the drag coefficient was observed to be two and a half times the predicted open ocean value. Significant wind stress steering is observed within 2 km of the inlet mouth, which is observed to be correlated with the horizontal current shear. Other mechanisms such as the reduction in wave celerity or depth‐limited breaking could also play a role. It was determined that outside the influence of these typical coastal processes, the open ocean parameterizations generally represent the wind stress field. The nearshore stress variability has significant implications for observations and simulations of coastal transport, circulation, mixing, and general surf‐zone dynamics. Key Points: A shallow‐water wind stress parameterization has yet to be developed Nearshore wind stress is significantly underestimated by conventional methods This has implications for studies and simulations of nearshore dynamics
Bibliography:istex:7953F3CD108ECCDD55F69235749584019339475A
ArticleID:JGRC21083
ark:/67375/WNG-6STN5T7M-Z
Office of Naval Research through research - No. N000141410643; No. N000141310144; No. N000141210448; No. N000141010409; No. N000141010379
ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
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ISSN:2169-9275
2169-9291
DOI:10.1002/2014JC010412