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13.10: Factors Affecting Wave “Size”

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    First, and perhaps most obvious, the wind speed plays a role in determining the size of waves that may be produced on the ocean. The faster the winds, the faster the transfer of energy to the ocean’s surface, and the bigger and more energetic the waves that are formed. Makes sense, right? There’s more energy transferred to the upper ocean.

    The length of time that the wind blows, wind duration, is also important. A short, sharp wind, no matter how fast, isn’t going to produce very big waves. You can sneeze on an aquarium—a sneeze has been clocked at about 40 mph—but you’re still not going to produce much in the way of waves. It takes time. So the longer the wind blows, the bigger and more energetic are the waves formed. But wait! There’s more.

    The distance over which the wind blows in the same direction, something called the fetch, also makes a difference. Long fetches mean that a larger area of the ocean receives energy from the wind; the ocean surface becomes more energetic. The greater the fetch, the bigger and more energetic the waves that are formed. Fetch explains why hurricanes with the fastest winds don’t always generate the biggest waves. Typically, the size of the wind field in a hurricane is smaller and the fetch shorter and more variable (because winds rotate around a hurricane) than the wind field in a large storm system. Low-pressure systems over the ocean may have fetches of hundreds of miles and wind speeds near hurricane strength. As a result, storms at sea tend to produce the largest waves observed in the ocean. Wind speed, wind duration, and fetch contribute to the formation of ocean waves. They act in combination to deliver energy to the ocean surface.

    Some forces remove energy from a wave. Progressive waves must contend with friction from the atmosphere as they move forward. Friction drains the energy from a wave. Strong winds may create whitecaps, the broken tops of wave crests that appear white because of the bubbles and foam present within them. Whitecaps remove energy from a wave. Other factors within the waves tend to dissipate their energy as well. At some point the energy transferred to the ocean at a given wind speed is balanced out by the energy lost by the waves. The steady state between energy-intensifying factors and energy-dissipating factors produces a fully developed sea. When this occurs, continued blowing of the wind at the same speed will produce no additional gains in wave height or energy. For these reasons waves always move at speeds slower than the wind speeds.

    This page titled 13.10: Factors Affecting Wave “Size” is shared under a CC BY 4.0 license and was authored, remixed, and/or curated by W. Sean Chamberlin, Nicki Shaw, and Martha Rich (Blue Planet Publishing) via source content that was edited to the style and standards of the LibreTexts platform.