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8.12: Langmuir Circulation

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    In addition to currents generated by Ekman transport, winds cause a completely different type of near-surface motion in which the upper few meters of water flow in corkscrew-like motions. These motions, called Langmuir circulation, are generated when the wind blows across the sea surface at speeds in excess of a few kilometers per hour.

    In Langmuir circulation, water travels in helical vortices aligned in the direction of the wind (Fig. 8-20). The helical vortices are stacked side by side and rotate in alternating directions like convection cells (CC3). Within each cell, water moves across the surface, sinks at a line of downwelling between two cells, moves back under the surface, and rises at a line of upwelling between two cells, while still moving in the wind direction (Fig. 8-20a).

    fig-ch01_patchfile_01.jpg
    fig-ch01_patchfile_01.jpg
    fig-ch01_patchfile_01.jpg
    fig-ch01_patchfile_01.jpg
    Figure 8-20. Langmuir circulation. (a) Moderate but persistent winds produce corkscrew-like motion of the upper few meters of water. Long linear cells of this helical motion line up alongside each other in the direction of the wind. Adjacent cells rotate in opposite directions, and alternating convergences and divergences form between them. (b) Convergences between Langmuir circulation cells are visible in this photo as the windrows of foam that collect at the convergences when the wind is blowing strongly.

    The width and depth of the Langmuir cells are determined by the wind speed and may be limited by shallow water or a shallow pycnocline. Typical cells are a few meters deep and a few meters to about 30 m wide. The top of the downwelling zone between two Langmuir cells is a sea surface convergence. Any oil, debris, or foam that is floating on the surface when Langmuir circulation is established is transported by the circulation to a convergence. The convergence zones are readily observable in lakes or oceans as the linear or nearly linear windrows of floating material that form when strong winds blow (Fig. 8-20b). The distance between two of the parallel windrows is equal to twice the width of each Langmuir cell.

    Langmuir circulation, together with wave action, is known to be very important in mixing the upper layers of water—a key process in the transport of dissolved gases and heat between the ocean and atmosphere (Chap. 7).

    8.12: Langmuir Circulation is shared under a not declared license and was authored, remixed, and/or curated by LibreTexts.

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