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Rip current observations via marine radar
Haller, M.C.; Honegger, D.; Catalan, P.A. (2014). Rip current observations via marine radar. J. Waterway Port Coast. Ocean Eng. 140(2): 115-124.
In: Journal of Waterway, Port, Coastal, and Ocean Engineering. American Society of Civil Engineers (ASCE): New York, N.Y.. ISSN 0733-950X; e-ISSN 1943-5460, more
Peer reviewed article  

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Author keywords
    Rip currents; Radar; Surf zone; Nearshore hydrodynamics.

Authors  Top 
  • Haller, M.C.
  • Honegger, D.
  • Catalan, P.A.

    New remote sensing observations that demonstrate the presence of rip current plumes in X-band radar images are presented. The observations collected on the Outer Banks (Duck, North Carolina) show a regular sequence of low-tide, low-energy, morphologically driven rip currents over a 10-day period. The remote sensing data were corroborated by in situ current measurements that showed depth-averaged rip current velocities were 20–40?cm/s whereas significant wave heights were Hs=0.5–1?m. Somewhat surprisingly, these low-energy rips have a surface signature that sometimes extends several surf zone widths from shore and persists for periods of several hours, which is in contrast with recent rip current observations obtained with Lagrangian drifters. These remote sensing observations provide a more synoptic picture of the rip current flow field and allow the identification of several rip events that were not captured by the in situ sensors and times of alongshore deflection of the rip flow outside the surf zone. These data also contain a rip outbreak event where four separate rips were imaged over a 1-km stretch of coast. For potential comparisons of the rip current signature across other radar platforms, an example of a simply calibrated radar image is also given. Finally, in situ observations of the vertical structure of the rip current flow are given, and a threshold offshore wind stress (>0.02?m/s2) is found to preclude the rip current imaging.

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