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Wave That Shook the World
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Classroom Activity
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Objective
To calculate approximate speeds and travel times for sample
tsunamis.
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copy of the "Tracking Tsunamis" student handout (PDF
or
HTML)
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copy of the "Tsunami Scenarios" student handout (PDF
or
HTML)
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copy of the "World Map" student handout (PDF
or
HTML)
- calculator with square root function
- drawing compass
- ruler
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Review subduction zones and how earthquakes occur in these
zones. (See Activity Answer for more
information.) Draw a subduction zone on the board and review
with students how the December 26, 2004, earthquake off of the
Sumatran coast created a tsunami: A massive displacement of
water from its equilibrium position caused the tsunami. Gravity
worked to restore the water to its equilibrium position. The
waves traveled from their place of origin in all directions and
energy from the quake was transferred by the water.
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Tsunamis, because of their long wavelengths, lose little energy
as they travel. (The rate at which a wave loses energy is
inversely proportional to its wavelength.) Inform students that
there is a formula that can be used to estimate the speed of the
wave created from this energy. The formula is used to measure
the speed of ocean waves, like tsunamis, that have very long
wavelengths relative to the depth of the water. Tsunamis can
have wavelengths greater than 700 kilometers (the average ocean
depth is 3-4 kilometers). The formula estimates the tsunami's
speed while it is in deeper waters (as it approaches shallower
coastal waters, the tsunami slows down, its wavelength shortens,
and its height increases).
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Brainstorm with students some factors that may play a role in
the speed of a tsunami. (Student responses may include the
magnitude of an earthquake, the amount of displaced water, and
the depth of the water.) Tell students that the formula to
approximate tsunami speed considers the depth of the water and
the acceleration due to gravity. The formula is:
where speed (meters/second) = square root of
g (acceleration due to gravity, which is 9.81
meters/second2) x d (water depth in meters)
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Have students work with a partner. Provide each team with a copy
of the handouts and other materials. Review the handouts with
them. Tell students that they will use the speed formula to
calculate tsunami speed and determine the time each tsunami
takes to travel to specific locations in each of the scenarios
presented. Students can check their distance estimates at
www.wcrl.ars.usda.gov/cec/java/lat-long.htm
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Students will need to convert their answers, which will be in
meters/second, to kilometers/hour. Help students think how they
might move the decimal point to accomplish the last step in this
conversion.
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To conclude, hold a class discussion about the order in which
the tsunami will strike each location (1st,
2nd, or 3rd). Have teams share some ways
people at each location might prepare for the approaching
tsunami. (Some considerations are evacuating people to high
ground, alerting hospitals, deciding whether there is time for
help from outside the country, or sending people away by boat.)
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As an extension, ask students to research why and how the
Pacific Tsunami Warning Center was developed and what future
plans are being formulated for a worldwide tsunami warning
system.
A tsunami is a series of waves created in a body of water by a
disturbance that vertically displaces the water column. Tsunamis are
not tidal waves (they are not caused by the forces that create
tides). An epicenter is the point on Earth's surface straight above
where an earthquake originates.
Water waves are grouped by the forces that cause or generate them
(generating forces) and those that restore equilibrium (restoring
forces). The generating forces are different for tsunamis and
wind-driven waves, but the restoring force for both is gravity.
Wave Comparison Chart
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Kind of Wave
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Mode of Generation
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Range of Wavelength
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Wave Frequency (Period)
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Wave Speed
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wind-driven
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local or distant winds that blow across the ocean's surface
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about 100 m to 200 m
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5 s to 20 s
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about 40 to 90 km/h (40 km/h, the speed of a moped, is most
common)
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seismic-sea wave (tsunami)
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sub-marine earthquakes (most tsunamis); also created by
volcanic eruptions, landslides, underwater explosions, and
meteor impacts
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from 100 m to >500 km; are at least three times the ocean
depth at which the wave was generated
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10 min to 2 h
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variable, up to 1,000 km/h (the speed of a jet plane)
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Most tsunamis are created by sub-marine earthquakes that occur at
subduction zones. At these zones, one tectonic plate is moving or
subducting beneath its neighboring plate. Many things can happen at
these sites to trigger a tsunami. At Sumatra, stick-slip friction
occurred. The upper plate dragged downward with the lower plate and
then the upper plate became deformed, built up strain energy, and
then snapped up. The magnitude of an earthquake determines how much
energy is released and then transferred by the water. The
earthquake's magnitude also plays a role in how high above sea level
the water level rises. Magnitude does not play a large role in the
tsunami's speed.
Several factors affect the height of a tsunami wave and the damage
it can cause as it approaches and reaches the shore—the energy
the wave carries; the tides, whether high or low; and the land
formation and features.
Scenario A
The Seward, Alaska, tsunami created at an ocean depth of 4,000 m is
calculated to travel at 713 km/h. The travel times to each location
are:
Kodiak, Alaska: about 32 minutes
Kauai Island, Hawaii: about 6 hours
Kwajalein, Marshall Islands: about 9 hours 26 minutes
Scenario B
The Ka Lae, Hawaii, tsunami created at an ocean depth of 4,500 m is
calculated to travel at 756 km/h. The travel times to each location
are:
Dutch Harbor, Alaska: about 5 hours 6 minutes
Kwajalein, Marshall Islands: about 5 hours 30 minutes
Samoa: about 5 hours 30 minutes
Scenario C
The Gran Canaria, Canary Islands, tsunami created at an ocean depth
of 3,500 m is calculated to travel at 667 km/h. The travel times to
each location are:
Terceira, Azores: about 2 hours 21 minutes
Safi, Morocco: about 1 hour 5 minutes
St. Johns, Newfoundland: about 5 hours 44 minutes
Web Sites
NOVA Web Site—Wave That Shook the World
www.pbs.org/nova/tsunami/
In this companion Web site to the program, find out about how well
officials can prepare for the next big tsunami, read an Ask the
Expert feature, see how the Indonesian event unfolded, and delve
into the global history of these seismic sea waves.
Calculating the Threat of Tsunami
www.science.org.au/nova/045/045key.htm
Defines the term tsunami and includes information about wave energy.
Earthquakes and Society
www.umich.edu/~gs265/society/earthquakes.htm
Includes charts and information about earthquakes at subduction
zones.
The Great Sumatra Earthquake and Tsunami of December 2004
www.wilson.wnyric.org/t/drobison/regents/WellOrganized/tsunami.htm
Provides a five-part high-school level earth science lesson plan
that explores the geologic processes involved with the Indonesian
tsunami. Includes analysis of actual seismograms from which students
plot the earthquake's epicenter.
HyperPhysics: Tsunami
hyperphysics.phy-astr.gsu.edu/hbase/waves/tsunami.html
Includes graphics of subduction zones and describes how tsunamis
travel.
International Tsunami Information Center
www.prh.noaa.gov/itic/library/about_tsu/faqs.html
Answers frequently asked questions about tsunamis and lists the
largest historical tsunamis.
Life of a Tsunami
walrus.wr.usgs.gov/tsunami/basics.html
Explains tsunami speed and amplification.
Oceanography: Waves
www.poemsinc.org/oceano/waves.htm
Contains a map of locations for 13 tsunamis.
Physics of Tsunamis
wcatwc.arh.noaa.gov/physics.htm
Characterizes tsunamis and considers how they travel in different
water depths.
Tsunami
www.tulane.edu/~sanelson/geol204/tsunami.htm
Describes the physical characteristics of tsunamis and includes
definitions of wavelength, wave height, wave amplitude, wave
frequency, and wave velocity. Includes formulas for calculating
velocity.
Tsunami: Frequently Asked Questions
www.pmel.noaa.gov/tsunami_faqs.htm
Answers questions about causes of tsunamis and how they differ from
other waves.
Tsunami—Seismic Sea Wave
vulcan.wr.usgs.gov/Glossary/Tsunami/description_tsunami.html
Describes seismic sea waves and discusses four damaging tsunamis.
U.S. Search and Rescue Task Force: Tsunamis
www.ussartf.org/tsunamis.htm
Provides basic information about tsunamis, features 10 destructive
tsunamis, and presents tsunami safety rules.
Water Waves
electron4.phys.utk.edu/141/dec8/December%208.htm
Distinguishes between deep-water waves and shallow-water waves and
provides an example of a tsunami velocity calculation.
What is a Wave?
www.gmi.edu/~drussell/Demos/waves-intro/waves-intro.html
Defines a wave and illustrates examples of different waves.
WorldAtlas.com
worldatlas.com/aatlas/imageg.htm
Maps latitude and longitude for cities, towns, and villages.
Books
Ford, Brent A. and Sean P. Smith.
Physical Oceanography. Arlington, VA: NSTA Press, 2000.
Includes background information, lessons, and activities related to
water, waves, and the ocean.
Macquitty, Miranda and Frank Greenaway.
Eyewitness: Ocean. New York, NY: DK Publishing, Inc.,
1995.
Focuses on Earth's ocean environments and includes a section on
waves and weather.
Van Rose, Susanna. Eyewitness: Earth. New York, NY: DK
Publishing, Inc., 1994.
Discusses Earth and highlights modern oceanography, plate tectonics,
and the formation of the ocean floor.
The "Tracking Tsunamis" activity aligns with the following National
Science Education Standards and Principles and Standards for School
Mathematics.
Grades 5-8
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Science Standard B:
Physical Science
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Transfer of energy
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Energy is a property of many substances and is associated with
heat, light, electricity, mechanical motion, sound, nuclei, and
the nature of a chemical. Energy is transferred in many ways.
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Science Standard D:
Earth and Space Science
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Structure of the Earth system
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Lithospheric plates on the scales of continents and oceans
constantly move at rates of centimeters per year in response to
movements in the mantle. Major geological events, such as
earthquakes, volcanic eruptions, and mountain building, result
from these plate motions.
Mathematics Standard
Grades 6-8
Number and Operations
Grades 9-12
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Science Standard B:
Physical Science
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Motions and forces
Conservation of energy and the increase in disorder
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The total energy of the universe is constant. Energy can be
transferred by collisions in chemical and nuclear reactions, by
light waves and other radiations, and in many other ways.
However, it can never be destroyed. As these transfers occur,
the matter involved becomes steadily less ordered.
Interactions of energy and matter
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Waves, including sound and seismic waves, waves on water, and
light waves, have energy and can transfer energy when they
interact with matter.
Mathematics Standard
Algebra
Classroom Activity Author
Developed by WGBH Educational Outreach staff.
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