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17.3: Storm Surges

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    Storm winds blowing over shallow, continental shelves pile water against the coast. The increase in sea level is known as a storm surge. Several processes are important:

    1. Ekman transport by winds parallel to the coast transports water toward the coast causing a rise in sea level.
    2. Winds blowing toward the coast push water directly toward the coast.
    3. Wave run-up and other wave interactions transport water toward the coast adding to the first two processes.
    4. Edge waves generated by the wind travel along the coast.
    5. The low pressure inside the storm raises sea level by one centimeter for each millibar decrease in pressure through the inverted-barometer effect.
    6. Finally, the storm surge adds to the tides, and high tides can change a relatively weak surge into a much more dangerous one.

    See Graber et al (2006) and Section 15.5 for a description of the Advanced Circulation Model used by the National Hurricane Center for predicting storm-surges. To a crude first approximation, wind blowing over shallow water causes a slope in the sea surface proportional to wind stress. \[\frac{\partial \zeta}{\partial x} = \frac{\tau_{0}}{\rho gH} \nonumber \]

    where \(\zeta\) is sea level, \(x\) is horizontal distance, \(H\) is water depth, \(\tau_{0}\) is wind stress at the sea surface, \(\rho\) is water density, and \(g\) is gravitational acceleration.

    If \(x = 100 \ \text{km}\), \(U = 40 \ \text{m/s}\), and \(H = 20 \ \text{m}\), values typical of a hurricane offshore of the Texas Gulf Coast, then \(\tau = 2.7 \ \text{Pa}\), and \(\zeta = 1.3 \ \text{m}\) at the shore. Figure \(\PageIndex{1}\) shows the frequency of surges at the Netherlands and a graphical method for estimating the probability of extreme events using the probability of weaker events.

    Plot of storm surge height by frequency per year, by year for the Hook of Holland in the Netherlands.
    Figure \(\PageIndex{1}\): Probability (per year) density distribution of vertical height of storm surges in the Hook of Holland in the Netherlands. The distribution function is Rayleigh, and the probability of large surges is estimated by extrapolating the observed frequency of smaller, more common surges. After Wiegel (1964: 113).

    This page titled 17.3: Storm Surges 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.