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Coastal Processes and Hazards. Outline Why is this important? Definitions How waves work Interaction at shoreline Importance of beaches Human impacts.

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Presentation on theme: "Coastal Processes and Hazards. Outline Why is this important? Definitions How waves work Interaction at shoreline Importance of beaches Human impacts."— Presentation transcript:

1 Coastal Processes and Hazards

2 Outline Why is this important? Definitions How waves work Interaction at shoreline Importance of beaches Human impacts on beaches

3 Why is this important? 70% of Earth’s surface is water –Means a lot of coastlines In U.S. - 30 coastal states –Projection by 2010 75% of population will live within 75 km of coastline –1,358 people/coastal mile –High concentration of people and property!

4 Possible Hazards Already covered –Hurricanes, tsunami, nor’easters Discuss today –Waves, tides, erosion, sea level rise

5 Coastlines Regions where land meets sea Can be of different forms –Long sandy beaches –Rocky cliffs –Coral reefs

6 Sandy N. Carolina coastline Rocky coastline of Maine

7 Waves and Tides Key forces that act to alter coastlines Important for erosion, moving material along coast

8 How waves work Caused by wind blowing over water surface –Transfer energy from air to water 5-20 km/hr breeze: small (< 1cm high) ripples 30+ km/hr: full size waves

9 Wave height Depends on –Wind speed –Direction of wind blowing –Length of water over which wind is blowing –Consistency of wind direction

10 What is Water Doing? Particle of water rotates in place with circular orbit –Orbit decreases in size with depth

11 Orbital Motion You probably have felt the same motion in the waves!

12 Wave Description Wavelength (L) Wave Height Period (T) Related to velocity of the wave –V=L/T –Typical T of few-20 sec, L of 6-600 m means V of 3-30 m/s

13 Swells Interference of many sets of waves –Usually related to storms, multiple storms Occasionally constructive interference occurs –Produce very large waves (rouge waves) –Can sink ships, may impact shorelines

14 Waves Near Coastlines 1st: orbital motion changes to elliptical when depth is < 1/2 L –Why? Friction with bottom shallow-water wave deep-water wave

15 Waves Near Coastlines 2nd: wave slows down, L gets smaller –Leads to more water, energy in shorter length; taller waves

16 Waves Near Coastlines 3rd: at certain height (1:7 height to wavelength), wave is too steep and breaks –Topples forward, forms the bubbly, foamy stuff

17 Slope of Near-shore Impacts wave breaks If gently sloping bottom, waves break farther from shore If steeply sloping bottom, waves break closer to shore Rocky cliffs: break directly on rocks with large force

18 Wave Refraction As waves get closer to shore, they bend to a direction roughly parallel to shore –Wave refraction, similar to light Important for areas with bays and headlands –Headlands: water depth shallows quickly, waves slow and converge at this point –Bays: water in center is deeper, area is more protected

19 Bending of wave crests due to refraction as waves slow down in progressively more shallow water depths

20 Wave refraction concentrates energy at headlands, thereby causing increased erosion Wave refraction decreases energy at bays, thereby causing increased deposition

21 Longshore Drift Waves arrive at small angle to shore, go up on beach at an angle –Moves sand grains (and people) at an angle Very efficient at transporting sand to/from beaches

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23 Beach Shoreline made of sand/pebbles Important for recreation, housing Also as a natural barrier to absorb energy in breaking waves Various beach processes affect how much beach is present during the year

24 General Beach Cycle Summer –Generally fewer storms, lower wind speeds, waves with shorter L and height –Act to push offshore sand onshore, build wide, sandy beaches

25 Summer beach near San Diego, CA

26 Winter beach (same one) near San Diego, CA Note sandy beach is gone, due to large storm waves

27 General Beach Cycle Winter –More energetic storms, waves erode beach sand, carry offshore –With less sand, energetic waves can attack coastal features such as roads, houses

28 Human Impacts Humans like to live near the beach! –Nice climate –Great views –Additional food sources Want to minimize risk from big waves, hurricanes, erosion of cliffs and beaches

29 Human Impacts In order to mitigate hazards, we build –Seawalls –Dams –Groins –Jetties Structures have multiple impacts

30 Dams Dam rivers that add water, sand into ocean Many built to provide freshwater reservoirs for coastal communities Problem: sand in rivers adds to beach development. By cutting off this supply, adds to problem of shrinking beaches

31 Seawalls/Cliff Protection Build structure for protection of beach or cliff –Changes beach dynamics What happens? –Ocean waves break on wall because beach narrows –Steepens slope offshore, leads to larger waves –Can over time erode seawall or undercut base

32 Seawalls can cause beaches to disappear, construction of new seawalls over time Also, reduce attractiveness of coastline, property values

33 Seawall, coastal GA

34 Groins and Jetties Elongate mass (usually rock or concrete) built perpendicular to shoreline –Purpose: keep sand on the beach Problem: longshore drift still occurs –Leads to deposition on 1 side, erosion on other side

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36 Jetty in NJ - note longshore drift is from left to right here Groin leads to deposition updrift, erosion downdrift

37 Beach Replenishment Actively transporting sand onto a beach –Usually pump it from offshore Can be very expensive ($millions/mile of beach) May have to be repeated every year Examples: Waikiki, HI; Miami, FL

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39 1981 Miami Beach

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41 Next Time Stream/River Processes


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