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MAR 110: Lecture 16 Outline – Tides
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MAR 110 LECTURE #16
Tides
Tides Are Waves Tidal wave energy is concentrated at periods of approximately 12 and 24 hours. (ItO)
Equilibrium Tidal Forcing The theoretical equilibrium tidal ocean covers the whole Earth deeply enough so that the shallow water tidal waves can follow astronomical forcing as the Earth rotates below.
MAR 110: Lecture 16 Outline – Tides
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Gravitational Attraction A “body force” that draws mass together. (ItO)
Basic Dynamic Balance The centrifugal “force” of circular motion balances the gravitational attraction; so that our two “moons” do not crash into each other. (ItO)
MAR 110: Lecture 16 Outline – Tides
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The Earth-Moon Dynamic The Earth is so massive that the center of Earth-Moon system
rotation is located within the Earth. (ItO)
Earth-moon System: Tide–Producing Forces The Moon’s gravitational attraction creates a stationary oceanic bulge on the side of the Earth facing the Moon. The centrifugal “force” due to the spinning of the System produces the oceanic bulge on the side of the Earth facing away from the Moon (ItO)
MAR 110: Lecture 16 Outline – Tides
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Observed Ocean Tides Sea level records from different locations reveal tides that are dominated by the twice-a-day or semidiurnal tide (top) ofr the once-a-day or diurnal tide (bottom). A mixture of the two period tides is more common. (LEiO)
Once-a-Day or Diurnal Tide An Earth observer (the stick figure) standing on the Earth at a very high latitude observes a high tide once-a-day as indicated in the time chart below. (??)
MAR 110: Lecture 16 Outline – Tides
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Semi-Diurnal Tide
Equilibrium Tides An observer on the Earth rotates beneath a stationary double oceanic sea level bulge. An observer at the equator observes two high tides of different height each lunar day, as indicated in the time chart to the right. (ItO, LEiO)
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Spring – Neap Tides About every 14 days the range of the tidal sea levels cycles through a maximum called spring tides and a minimum called neap tides – as indicated by the sea level record to the left. This phenomena occurs because the sun and the moon each produce separate double oceanic sea level bulges, with the sun’s being about that of the moon, as illustrated to the right. During spring tides (a time of full or new moon), the solar and lunar double bulges add to each other to produce the largest tidal ranges. During neap tides ( a time of half moon), the solar and lunar tidal bulges subtract from one another. In short, the spring neap cycle in tidal range arises from the constructive and then destructive interference of the solar and lunar tidal sea levels. (??)
Realistic Ocean Tides On the real Earth oceans are contained in basins bounded by the continents; not covered by the ocean. Thus the astronomical tidal forcing creates a standing tidal wave in our idealized ocean basin that is meant to model the Atlantic Ocean. (ItO)
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Rotary Standing Wave in an Enclosed Basin The tidal waves in our idealized enclosed ocean basins are the rotary standing waves as illustrated above because of the effects of Earth rotation. Note how the sea level highs (and lows) rotate around a node in the center of the idealized basin – a point of no tide or amphidromic point in what is called an amphidromic system. (ItO)
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Cotidal Chart of an Amphidromic System The tidal action ina an amphidromic system can be neatly summarized in a cotidal chart, which looks like a wagon-wheel. Cotidal lines (the spokes) mark the location of high tide at each lunar hour during the tidal cycle. The corange lines (the circular wheel rim) mark the locations with the same tidal ranges. (ItO)
The Atlantic Ocean Amphidromic System The North Atlantic tidal system closely resembles an ideal amphidromic system with some deviation due to bathymetry. (ItO)
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Wave Reflection and Standing Waves A standing wave does not travel or propagate but merely oscillates up and down with stationary nodes (with no vertical movement) and antinodes (with the maximum possible movement) that oscillates between the crest and the trough. A standing wave occurs when the wave hits a barrier such as a seawall exactly at either the wave’s crest or trough, causing the reflected wave to be a mirror image of the original. (??)
Standing Waves Standing waves can also occur in an enclosed basin such as a bathtub. In such a case, at the center of the basin there is no vertical movement and the location of this node does not change while at either end is the maximum vertical oscillation of the water. This type of waves is also known as a seiche and occurs in harbors and in large enclosed bodies of water such as the Great Lakes. (??, ??)
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Seiche Period The wavelength of a standing wave is equal to twice the length of the basin it is in, which along with the depth (d) of the water within the basin, determines the period (T) of the wave. (ItO)
Bay Tides and their Period Another type of standing wave occurs in an open basin that has a length (l) one quarter that of the wave in this case, usually a tide. In this case the node is at the inlet of the basin with the antinode at the closed end. The most commonly used example of this type of standing wave is the Bay of Fundy. (ItO)
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Gulf of Maine/Bay of Fundy Tides The North Atlantic tidal excursions at the mouth of the Gulf of Maine (rather than direct astronomical forcing) drive the large tides in the Gulf of Maine/Bay of Fundy system, with the largest tidal ranges at the head of the Bay of Fundy. (ItO)
Bay of Fundy and Tidal Bores In regions with significant tides such as the Bay of Fundy it is not unusual for a tidal bore to form which is a wave or wall of water at the leading edge of the tide wave (right), particularly in rivers or narrow bays and passages. The tidal bore will continue upstream into the bay or river sometimes for a hundred miles or more (ex: the Yellow River in China). Since this wave or wall of water has the mass of the tide behind it, people can use it to push surfers or even boats upstream for long distances. (??, ItO, LEiO)
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