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9: Response of the Upper Ocean to Winds

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    If you have had a chance to travel around the United States, you may have noticed that the climate of the East Coast differs considerably from that on the West Coast. Why? Why is the climate of Charleston, South Carolina so different from that of San Diego, although both are near 32\(^{\circ}\)N, and both are on or near the ocean? Charleston has 125–150 cm of rain a year, San Diego has 25–50 cm, Charleston has hot summers, San Diego has cool summers. Or why is the climate of San Francisco so different from that of Norfolk, Virginia?

    If we look closely at the characteristics of the atmosphere along the two coasts near 32\(^{\circ}\)N, we find more differences that may explain the climate. For example, when the wind blows onshore toward San Diego, it brings a cool, moist, marine, boundary layer a few hundred meters thick capped by much warmer, dry air. On the East Coast, when the wind blows onshore, it brings a warm, moist, marine boundary layer that is much thicker. Convection, which produces rain, is much easier on the East Coast than on the West Coast. Why then is the atmospheric boundary layer over the water so different on the two coasts? The answer can be found in part by studying the ocean’s response to local winds, the subject of this chapter.

    • 9.1: Inertial Motion
      Equations of motion for water moving through the ocean under the influence of only the Coriolis force. Discussions of inertial currents formed from this source.
    • 9.2: Ekman Layer at the Sea Surface
      Ekman's solutions to the momentum equations for wind-driven currents as influenced by Earth's rotation at the ocean surface.
    • 9.3: Ekman Mass Transport
      Calculating the mass of water transported in the Ekman layer. Calculating volume transport from the mass transport.
    • 9.4: Application of Ekman Theory
      Applications of Ekman Theory, including coastal upwelling and oceanic mass redistribution from upwelling and downwelling that creates wind-driven geostrophic currents via Ekman pumping.
    • 9.5: Langmuir Circulation
      Overview of Langmuir circulation, another type of wind-generated current that spirals around an axis parallel to the wind deirection.
    • 9.6: Important Concepts
      Summary of major concepts covered in this chapter.

    This page titled 9: Response of the Upper Ocean to Winds is shared under a CC BY-NC-SA 4.0 license and was authored, remixed, and/or curated by Robert H. Stewart via source content that was edited to the style and standards of the LibreTexts platform.