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7.1: Dominant Forces of Ocean Dynamics

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    Only a few forces are important in physical oceanography: gravity, friction, and Coriolis (Table \(\PageIndex{1}\)). Remember that forces are vectors. They have magnitude and direction.

    1. Gravity is the dominant force. The weight of the water in the ocean produces pressure. Changes in gravity, due to the motion of the sun and moon relative to Earth, produce tides, tidal currents, and tidal mixing in the interior of the ocean.

      Buoyancy is the upward or downward force due to gravity acting on a parcel of water that is more or less dense than other water at its level. For example, cold air blowing over the sea cools surface waters, causing them to be more dense than the water beneath. Gravity acting on the difference in density results in a force that causes the water to sink.

      Horizontal pressure gradients are due to the varying weight of water in different regions of the ocean.
    2. Friction is the force acting on a body as it moves past another body while in contact with that body. The bodies can be parcels of water or air.

      Wind stress is the friction due to wind blowing across the sea surface. It transfers horizontal momentum to the sea, creating currents. Wind blowing over waves on the sea surface leads to an uneven distribution of pressure over the waves. The pressure distribution transfers energy to the waves, causing them to grow into bigger waves.
    3. Pseudo-forces are apparent forces that arise from motion in curvilinear or rotating coordinate systems. For example, Newton’s first law states that there is no change in motion of a body unless a resultant force acts on it. Yet a body moving at constant velocity seems to change direction when viewed from a rotating coordinate system. The change in direction is due to a pseudo-force, the Coriolis force.

      Coriolis Force is the dominant pseudo-force influencing motion in a coordinate system fixed to the Earth.
    Table \(\PageIndex{1}\). Forces in Geophysical Fluid Dynamics.
    Dominant Forces  
    Gravity Gives rise to pressure gradients, buoyancy, and tides.
    Coriolis Results from motion in a rotating coordinate system.
    Friction Is due to relative motion between two fluid parcels. Wind stress is an important frictional force.
       
    Other Forces  
    Atmospheric Pressure Results in inverted barometer effect.
    Seismic Results in tsunamis driven by earthquakes.
    Note that the last two forces in this table are much less important than the first three.

    This page titled 7.1: Dominant Forces of Ocean Dynamics 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.