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CATASTROPHIC EVENTS [J.K. Nakata, U.S. Geological Survey] Students in 7th grade should know that major geological events, such as earthquakes, volcanic eruptions, and mountain building, result from the movement of lithospheric plates. They should be able to describe and predict the impact upon Earth of different catastrophic events, including earthquakes and volcanic eruptions. CATASTROPHIC EVENTS TEACHER GUIDE GRADE 7 Teacher Background Information The alteration of Earth systems from both human interaction and catastrophic natural events can have devastating effects. Natural events can include earthquakes, volcanic eruptions, hurricanes, and gradual processes such as weathering, erosion and deposition. Human alteration from misuse, overuse, or pollution of natural resources can result in changes to soil, water, and air. What is the Earth’s Interior like? Until about 100 years ago, scientists believed that the Earth was one solid rock. But, through advances in technology (machinery allowing them to drill deeper into Earth’s crust and sensitive instruments allowing them to monitor Earth’s interior from the surface) they have been able to better infer what Earth’s interior is like. In order to understand the impact of catastrophic events, such as earthquakes and volcanoes, we must first understand what the Earth is composed of and how it behaves. The Earth is divided into four main layers. Located at the center of the Earth, the inner core is composed mostly of iron and nickel. It exists at such a temperature (4,3000C) that should be molten, but it is under such extreme pressure it remains solid. The outer core is composed of the same two metals and is molten at 3,7000C. CATASTROPHIC EVENTS TEACHER GUIDE GRADE 7 Teacher Background Information Most of Earth’s mass (70-80%) is in the mantle, which is composed of silicon, oxygen, magnesium, iron, aluminum, and calcium. The mantle is solid but can deform slowly in a plastic manner. The part of the mantle near the crust, about 50-100 km down, is especially soft and plastic because the material is near its melting point. This is referred to as the asthenosphere or the upper mantle. The mantle and crust above are cool enough to be tough and elastic, and are known as the lithosphere. The lithosphere is between about 100 and 250 kilometers deep. In total, the mantle comprises about 80 percent of the volume of Earth and is about 2900 km thick. The lower mantle, totally solid, flows slowly, at a rate of a few centimeters per year. Earth’s crust is the solid, outer part of Earth that we live on. It is much thinner than the other layers with an average depth of 30 to 40 km and is composed of the least dense minerals. The rock that makes up the continental crust has been dated to be about 3.8 billion years old. Being relatively cold (compared to the core and mantle) and thin (average depth of 30 - 40 km but as deep as 70 km beneath mountain ranges and as shallow as 6-11 km beneath the oceans). The crust is rocky and brittle. It can fracture during earthquakes or other movements. Due to the temperature difference between the Earth’s surface and the outer core, and the ability of the crystalline rocks at high pressure and temperature to undergo slow, creeping, viscous-like deformation over millions of years, there is a convective circulation of material within the mantle: hot material rises from the lower mantle, while cooler (and heavier) material sinks downward from the upper mantle. The latter often occurs in the form of large-scale downward thrusting of the lithospheric plates at plate boundaries called subduction zones. Convection within the Earth’s mantle is a chaotic process (in the sense of fluid dynamics), which is thought to be an integral part of the motion of the lithospheric plates. Plate motion should not be confused with the older term continental drift which applies purely to the movement of the crustal components of the continents the movements of the lithosphere and the underlying mantle are coupled since the descending lithosphere is the dominant driving force for convection in the mantle. POSSIBLE MISCONCEPTION: Students may believe that the Earth’s mantle is liquid. They may also believe that the plates are composed of crust only and “float” on top of a liquid mantle. When the lithospheric plates move past one another or bump into each other, phenomena such as earthquakes and volcanoes occur. The two-dimensional contact where two or more plates slide along each other (either sideways or one plate sliding up when the other slides down) are called faults. It is along these faults that earthquakes typically occur. Volcanoes form at locations where partial melting occurs just beneath the lithosphere (such as a “hot spot” below a plate, or a fissure where two plates are coming apart such as the mid-Atlantic rift). At locations where two plates collide, they can both buckle upward, forming mountain ranges containing many smaller faults. CATASTROPHIC EVENTS TEACHER GUIDE GRADE 7 Teacher Background Information What makes an earthquake occur? When two plates as large as continents slide past (or over/under) each other, there are points along the fault contact where tremendous pressure builds. After a threshold limit is reached, the release of that pressure can be so massive that it causes an earthquake. This sudden movement of these two large places causes a vibration that can be likened to a bell playing a single, very low note. This note may last for only a few seconds, but for that time it is so low that it is felt as an earthquake. Depending on the depth and timing of the pressure release, and the characteristics of the rocks on either side of the fault, the quake is felt as either an up-and-down motion or as a side-to-side motion of the land surface. This vibration can shake large masses of land hundreds of miles away from where it originated (the epicenter) or be so small so that it is never even noticed. Although people can feel earthquakes in many places on the Earth, there are two parts of the world where the majority of quakes take place. These locations have tall mountains (on the edge of the upper plate) existing next to deep ocean bottoms (the edge of the lower plate is being subducted beneath the other). One of these “belts” circles the Pacific Ocean and the other is the mountainous region next to the Mediterranean Sea, a section of Northern Africa and Asia Minor and Southern Asia. What are the effects of earthquakes? Earthquakes are among the deadliest of natural catastrophes. The average death toll in the 20th century has been 20,000 people annually. Most deaths are caused by the collapse of houses, bridges, and other structures. Although buildings located along a fault may be torn apart, more damage is caused by the shaking alone, which can topple structures far from the actual fault. Earthquakes also cause indirect damage through landslides, fires, and the collapse of dams. The civil disorder that follows can lead to disruption of food and water supplies and sanitation systems, causing starvation and the spread of disease. Earthquakes that occur under or near the ocean can also generate tsunamis or seismic sea waves once called tidal waves. With heights up to 15 m (50 ft.), these waves can cross an ocean in several hours, inflicting damage upon shores far from the earthquake itself. How are volcanoes formed? There are about 1300 active volcanoes on the surface of the Earth. There are many more under the surface of the oceans. Volcanoes have been divided into three main groups by scientists based on the material of the volcano and its shape: shield volcanoes, cinder cones, and composite volcanoes. Volcanoes have different shapes depending on the kind of material that comes out of the Earth as well as other factors. A single vent may create a volcanic dome that usually exists inside an existing crater or on the side of a composite volcano. Composite volcanoes or strato-volcanoes are usually tall, symmetrically shaped, with steep sides, sometimes rising 10,000 feet high. They usually alternate lava and ash eruptions. (Mt. Fuji is a prime example of a symmetrical composite volcano. Mt. St. Helens used to be symmetrical until it erupted in May of 1980. Now it is an asymmetrical composite volcano). Shield volcanoes have a more flattened shape than a composite volcano. Shield volcanoes form from very fluid lava and are made up almost exclusively of thin rapidly flowing lavas that spread out. Shield cones are low, very broad, and gently sloping. Hawaiian volcanoes are shield volcanoes. Cinder cones form from very violent, explosive eruptions or red, hot magma cinders and ash. These layers of pyroclasts (fragments of volcanic rock blasted into the air from a vent or fissure) settle around the main vent and build a steep sided cone. Very little lava is erupted from a cinder cone. Mt. Vesuvius in Italy is a famous cinder cone. Volcanoes can have drastic effects on the surface CATASTROPHIC EVENTS TEACHER GUIDE GRADE 7 Teacher Background Information of the Earth. These can happen over a short period of time such as the explosion of Mt. St. Helens (an andesite volcano with sticky, explosive lava containing oceanic or continental crust) or over a longer amount of time such as the development of the Hawaiian Islands (formed from a different zone and contains no continental or oceanic crust melted into it). No matter how quickly these events happen they represent the result of the same effect. Essentially this is the escape of molten rock and other materials from the mantle to the surface of the Earth. There are three main ways that volcanoes are made. One is where tectonic plates are pulling apart as along mid-ocean ridges. This is how Iceland was formed. A second way is the kind caused by the subduction of one of the dozen or so large plates under one of the other ones. Subduction happens when one plate slides under another one. An example of this is when the Pacific plate is subducted under the North American plate. A huge amount of pressure and heat is generated causing the rock to melt. This melted rock is forced up through cracks in the crust to emerge as lava from a volcano. This helps to explain why the Pacific Rim is surrounded by volcanoes. Finally, some volcanoes are found far from the edge of plates. These are created over hotspots in the crust. Hotspots are the points on the crust of the Earth where the hot magma reaches the crust. At these points, the magma burns a hole in the crust like a blow torch. Some of the magma escapes through this hole to the surface. In the case of the Hawaiian Islands, they are constantly being pulled over this stationary hotspot by the movement of the plate they are on. The hotspot continues to melt its way up to the surface creating another in the chain of islands we know as Hawaii. What are the effects of volcanic eruptions? Some of the power of volcanic explosions comes from the huge amount of carbon dioxide gas that is dissolved in the magma. Remember that magma is molten rock before it comes to the surface. As the magma gets closer to the surface the pressure on it drops and the gas dissolved in it starts to form bubbles. They get bigger and bigger until they force the magma out of the volcano. However, the most important element in an explosive eruption may be water. As the pressure drops, the superheated water is allowed to flash into steam at something like 6000 times the volume. What are lahars? Some volcanic eruptions result in dangerous mudslides known as lahars. Throughout history, lahars have killed many more people than volcanic eruptions themselves. Looking and behaving a lot like concrete, they are fluid when moving, then solid when stopped. Lahars move quickly down a mountain frequently reaching speeds between 20 and 40 miles per hour. They pack a powerful destructive force capable of moving great quantities of debris (house-size boulders, trees, etc.) for long distances in a short amount of time. They have been recorded moving several dozen meters in just one second. The result of lahars is usually a deposit of sediment that can range anywhere from a few yards to hundreds of yards thick. POSSIBLE MISCONCEPTION: Students may not understand that deposition can also be considered a constructive force such as when depositing sediment to build up land. It is believed that the Isthmus of Panama was created primarily from the combined constructive forces of erosion and deposition. CATASTROPHIC EVENTS TEACHER GUIDE GRADE 7 OPTIONAL ACTIVITY MODELING EARTH’S INTERIOR Suggested Time: 15 Minutes If students are having difficulty understanding the layers of Earth you might want to try this very basic activity. Students will create an edible model of the Earth's interior to aid in learning about the three main parts of the Earth. This activity may be especially helpful for ELL students and other students that may not understand how the Earth is layered. Teacher Guide Materials Red hot candies Marshmallow (large) Melted chocolate Toothpicks Small sheet of wax paper Directions: 1. First take a red hot candy, which represents the core of the Earth and squeeze it into the center of a marshmallow, which represents the mantle. 2. Then take the filled marshmallow, stick a toothpick in it, and plunge it into melted chocolate. Use a crock pot or microwave to melt the chocolate, which hardens as it cools to become the thin crust of the Earth. 3. Place the chocolate covered marshmallow on wax paper to harden. Then eat. 4. Show students a picture of the Earth’s layers. Have them compare the picture of Earth's layers to their marshmallow. Similarities: They both have a center core that is red hot. The middle is also mushy and soft just like the material that makes up the Earth's mantle. The thin outside layer around the marshmallow was a hot liquid but became a thin solid surface when it cooled just like the Earth's crust. Differences: The crust on the model is uniform thickness the Earth’s crust is not; the red hot candy, which represents the core, does not have a solid inner core and a liquid outer core. Assessment: Students draw a picture of the Earth's layers and label the core, mantle, and crust. SAFETY NOTE: Be sure to check for food allergies and food restrictions list. Some dietary and religious restrictions will not allow students to eat marshmallows since they are made with cow’s hooves. This is also a good opportunity to review with students when it is proper and acceptable to “eat” in the lab or during science and when it is not. CATASTROPHIC EVENTS TEACHER GUIDE GRADE 7 ENGAGE SHAKING IT UP Suggested Time: 45 Minutes Teaching Guide Materials For each group: In this activity students will simulate liquefaction and discover what happens to land when an earthquake shakes it up. You may decide to do this activity as a demonstration or in small groups. Heavy metal pan Sand Water Directions: Smooth brick Rubber mallet 1. Fill the pan about 3/4 full with sand. 2. Place the pan on a level surface. Pour water into the pan to just below the surface of the sand. 3. Insert the brick, skinny end up, into the wet sand so it resembles a building. 4. Let the pan stand for a few minutes, allowing the water and sand to settle. 5. Now, gently tap the side of the pan with the rubber mallet. 6. Notice what happens to the sand and the brick. What happened? Students should notice that the sand got all squishy and the brick fell over. Mixing water with the sand allows the sand grains to settle until they touch each other. There will be water in pore space between the grains, but the mixture will behave as a solid. By striking the container with the mallet, the sand is squeezed (or sheared) closer together. In order to do this, the particles have to push the water between them out of their way. In the case of an earthquake (simulated by striking the container with the mallet), the squeezing done by the shockwave happens very quickly and the water does not have time to flow out of the way of the sand particles. This results in the particles pushing on the water and causing an increase in water pressure as the particles try to move into a denser configuration. This increased pressure causes the force at the contact points between the sand particles to decrease, and if the pressure is high enough it can reduce the interparticle forces to zero, essentially trying to “float” the sand particles away from each other for a very short time. This is known as liquefaction. The loss of strength occurs because there is no contact between the grains of sand; the mixture of sand is suspended in water for a short time. Extension: This activity can be repeated with smaller centimeter cubes placed around the “building”. Have students notice what happens to smaller structures during an earthquake. Note: This is a special situation with weak rock and water and would not happen in solid rock. CATASTROPHIC EVENTS TEACHER GUIDE GRADE 7 EXPLORE CATASTROPHE Suggested Time: 90 Minutes Begin by reading “When the Catfish Shakes” from Dangerous Planet: Natural Disasters that Changed History (pages 38 – 41) about the 1923 earthquake which struck Kanto, Japan. As you read, lead a discussion of what caused the damage (fires, aftershocks, falling structures, etc.) Elicit ideas on how the damage might have been prevented. Pictures of the damage caused by this 7.8 quake can be found at: http://www.japan-guide.com/a/earthquake. Teaching Guide Materials For teacher: Dangerous Planet: Natural Disasters That Changed History For each group: Internet access Now show students a slideshow of damage caused by the October 17, 1989 earthquake in Loma Prieta, California http://pubs.usgs.gov/dds/dds-29/slideshow.pdf and discuss the damages seen. Note: If you do not have access to the Internet, these pictures will be on the accompanying CD. In this lesson, students will consider the threats that natural disasters like volcanoes and earthquakes pose for humans. They will then compare and contrast two disasters. Ask students why they think some earthquakes and volcanic eruptions harm people and damage property, while other similar events do not. List students' responses on the board or overhead; save the list for later use. The list will likely include ideas such as the intensity or magnitude of the event, the number of people living near the event, methods of warning about the event, and level of preparedness for the event. Break the class into at least four small groups. Assign each group to research and take notes about a set of natural disasters listed below (two earthquakes, or two volcanic eruptions) on the Catastrophic Event template. More than one group can research the same set of events. These questions can guide students' research: When did the event occur? Where did it occur? What were the characteristics of the event? How many people were injured or killed? What kind of property was damaged? What was the cost of the property damage? Suggested catastrophic events for student to compare: Earthquakes Izmit, Turkey, on August 17, 1999 http://quake.wr.usgs.gov/research/geology/turkey/ Loma Prieta, California, on October 17, 1989 http://pubs.usgs.gov/dds/dds-29/ Earthquake comparisons, www.eas.slu.edu CATASTROPHIC EVENTS TEACHER GUIDE EXPLORE GRADE 7 Teaching Guide Volcanoes Soufriere Hills, Montserrat, in 1997 Mount Pelée, Martinique, on May 8, 1902: http://www.mvo.ms/ http://www.zananas-martinique.com/en-saint-pierre-martinique/pele-mount-eruption-1902.htm Mt. Pinatubo, Philippines in 1991 http://volcano.und.nodak.edu/vwdocs/volc_images/southeast_asia/philippines/pinatubo.html In addition to earthquakes and volcanoes, you may allow students to research catastrophic destruction caused by other forces of nature, such as tornados, hurricanes, flash floods and tsunamis. Here are some suggested events. They should still compare two different sets of events, using the same graphic organizer to take notes. Tornadoes - http://www4.ncdc.noaa.gov/cgi-win/wwcgi.dll?wwEvent~Storms In Kansas, on May 3, 1999. Search by selecting: State: Kansas; Begin Date: 05/03/1999; All Counties; Event Type: Tornadoes; F4 Tornadoes In Arkansas, on January 21, 1999. Search by selecting: State: Arkansas; Begin Date: 01/21/1999; All Counties; Event Type: Tornadoes; F4 Tornadoes Hurricanes Hurricane Wilma – October 19, 2005 Hurricane Katrina – August 29, 2005 Hurricane Camille – August 17, 1969 http://reference.aol.com/planet-earth/natural-disasters/hurricanes http://www.nationalgeographic.com/forcesofnature/forces/hurricanes.html http://library.thinkquest.org/16132/html/hurricane.html Tsunamis Tsunami in the Indian Ocean – July 17, 2006 Tsunami in Sumatra, Indonesia – December 26, 2004 Tsunami in Papua, New Guinea – July 17, 1998 http://www.cbc.ca/news/background/forcesofnature/tsunamis.html http://library.thinkquest.org/16132/html/tsunami.html http://www.teachervision.fen.com/natural-disasters/weather/31103.html Note: If computers or the internet are not available, these pages can be printed out for student use or library books can be used. CATASTROPHIC EVENTS TEACHER GUIDE EXPLORE Teaching Guide CATASTROPHIC EVENT: Topic Date of occurrence: Description of event: Measurement of event: Damage caused: Impact on Human Life: Other information: Source: GRADE 7 Summary of findings: CATASTROPHIC EVENTS TEACHER GUIDE EXPLAIN COMPARING CATASTROPHES Suggested Time: 45 Minutes As groups finish their research, provide chart paper or poster board. Each group should write the names of the two events at the top of the paper. Then each group should make a table, Venn diagram (with illustrations, if desired), or illustrate in another way the similarities and differences between the two events. GRADE 7 Teaching Guide Materials For each group: Chart paper Markers Discuss and summarize students' findings. Even though groups studied two completely different kinds of natural disasters, students likely gathered data on common aspects, which may include different periods in history - advances were made in scientific understanding, prediction capabilities, and community preparedness location level of preparation time of day or year Refer back to the class list of responses to the opening question: "Why do some earthquakes and volcanic eruptions harm people and property, while other similar events do not?" Ask students which, if any, of their original responses do not seem to apply to their research findings. Would they reconsider any of their original answers? Can they add anything to their original list? Assessment: Use the rubric attached or create your own to evaluate students' work based on the amount of detail and accuracy in oral and written presentations and on the use of research. Students should have compared data for natural disasters, analyzed the magnitude and impacts of these events, and identified and compared past and current knowledge about a natural hazard, and cited how the impacts of that hazard might be minimized with scientific research. Adapted from: MarcoPolo: NATURAL HAZARDS: SAME FORCES, DIFFERENT IMPACTS http://www.nationalgeographic.com/xpeditions/lessons/15/g68/fonhazards.html CATASTROPHIC EVENTS TEACHER GUIDE GRADE 7 EXPLAIN Teaching Guide Catastrophic Events Student Name: CATEGORY Internet Use Quality of Informatio n Graphic Organize r Comparison of Events Sources _ 4 3 Teacher Name: 2 1 Successfully uses suggested internet links to find information and navigates within these sites easily without assistance. Usually able to use suggested internet links to find information and navigates within these sites easily without assistance. Occasionally able to use suggested internet links to find information and navigates within these sites easily without assistance. Needs assistance or supervision to use suggested internet links and/or to navigate within these sites. Information clearly relates to the main topic. It includes several supporting details and/or examples. Information clearly relates to the main topic. It provides 1-2 supporting details and/or examples. Information clearly relates to the main topic. No details and/or examples are given. Information has little or nothing to do with the main topic. Graphic organizer is accurate, neat and thoroughly completed. Graphic organizer is accurate and thoroughly completed. Graphic organizer is accurate and most sections have been completed. Graphic organizer has inaccuracies or has not been completed. Diagrams and illustrations are neat, accurate and clearly compare the two events researched Diagrams and illustrations are neat, accurate and compare the two events researched. Diagrams and illustrations are accurate and show some comparisons between the events researched. Diagrams and illustrations are not accurate OR do not compare the events researched. All sources (information and graphics) are accurately documented in the desired format. All sources (information and graphics) are accurately documented, but a few are not in the desired format. All sources (information and graphics) are accurately documented, but many are not in the desired format. Some sources are not accurately documented. Final Grade - CATASTROPHIC EVENTS TEACHER GUIDE ELABORATE WHOSE FAULT IS IT? Suggested Time: 45 Minutes GRADE 7 Teaching Guide Materials For each group: Begin by showing students pictures of damage caused by the August 18,1999 earthquake in Golcuk, Turkey: 80 sugar cubes http://www.eas.slu.edu/Earthquake_Center/TURKEY/, or 2 shallow cardboard boxes http://www.ngdc.noaa.gov/seg/hazard/slideset/46/46_thumbs.shtml 1 metric ruler 1 pair of scissors Discuss with students why they think the mosque, built during the Ottoman Empire (1300 – 1900) might have survived this earthquake, while those built during the modern era did not. It is interesting to note that Turkish leaders now believe that many contractors of the modern buildings succumbed to bribes and used inferior materials and did not follow the architects’ designs for creating “earthquake proof” buildings. Graph paper 10-20 marbles 4 short rubber bands Stapler or duct tape The object of this activity is to teach students that one of the main causes of damage in an earthquake is the collapse of buildings not strong enough to withstand the shaking. They will model some of the investigations that engineers and architects go through to try to design buildings rigid enough to withstand the shock, but flexible enough to “give” a little under the stress. Student Directions: Build a shake tray 1. Place one cardboard box on a table and, with the scissors, cut the bottom out of the second box so that it fits inside the first box with a 2-cm clearance around each side. 2. Place the marbles in the first box and rest the cut piece of cardboard on top of them. 3. Use the stapler or tape to attach one rubber band to each inside corners of the first box and then to the corners of the cardboard insert. The rubber bands should be taut, but not overstretched. 4. To start the tray shaking, pull the insert toward one side of the box and let it go. CATASTROPHIC EVENTS TEACHER GUIDE ELABORATE GRADE 7 Teaching Guide WHOSE FAULT IS IT? - CONTINUED Create an earthquake-proof building 1. Using the sugar cubes as building elements, assemble several structures that each measure at least two sugar cubes high. Each structure must be different. You must have space inside of your structure that would represent the space people would use. Illustrate each of your structures on your graph paper. 2. Mark the center of the shake tray with a “X” to represent the epicenter. Place the structure on the shake tray an equal distance from the epicenter. Shake the tray to see how they stand up to your quake. Record the order in which the buildings fell. 3. Hold a design competition with your friends. See who can build an earthquake-proof structure using the most materials. Questions for students: 1. What structural shapes seem to survive quakes best? Can you think of any existing buildings that use this type of design? 2. What type of earthquake motion was your shake tray simulating? Are there other motions in a quake? How might you duplicate them? 3. Do you think that it is possible to build an earthquake-proof structure? Why or why not? 4. How does the amount of shaking time affect building damage? 5. How does the strength of the shaking affect building damage? Note: Students don't really need the marbles, but they make an impression as they move around in the box. The rubber bands hold the inside tray up without any problem. Students should find out that the more space between the inner tray and outer box the greater the "earthquake". Extensions: Have students try varying the amount of time and the strength of the shaking by pulling on the side of the cardboard for longer periods of time or creating more tautness. Let students experiment with the spacing between the shake tray and the box to see what effect it has on the structures. Show students National Geographic’s Forces of Nature. At this site students can try to build a building that will withstand an earthquake. http://www.nationalgeographic.com/forcesofnature/film/ - click on “Earthquakes” in the Interactive box on the left side of the page. CATASTROPHIC EVENTS TEACHER GUIDE GRADE 7 EVALUATE Teaching Guide “Whose Fault Is It?” Rubric CATEGORY 4 Function Structure functions extraordinarily well, holding up under atypical stresses. Structure functions well, holding up under typical stresses. Structure functions pretty well, but deteriorates under typical stresses. Fatal flaws in function with complete failure under typical stresses. Data taken several times in a careful, reliable manner. Data taken twice in a careful, reliable manner. Data taken once in a careful, reliable manner. Data not taken carefully OR not taken in a reliable manner. Directions were followed and creatively modified in ways that made them even better. Directions were followed and there was an attempt at creative modification to make them even better. Directions were appropriately followed Directions were not followed which led to a structure that performed poorly. Plan is neat with clear measurements and labeling for all components. Plan is neat with clear measurements and labeling for most components. Plan provides clear measurements and labeling for most components. Plan does not show measurements clearly or is otherwise inadequately labeled. Several entries made and all are dated and neatly. Several entries are made and most of the entries are dated and neatly entered. Several entries are made and most of the entries are dated and legible. Few entries are made AND/OR many entries are not dated or very difficult to read. Data Collection Directions Plan Journal/Log Appearance 3 2 1 CATASTROPHIC EVENTS TEACHER GUIDE READING CONNECTION GRADE 7 Teaching Guide Volcanoes (The Wonders of Our World) Neil Morris. Crabtree Publishing Co., 1995. Written at about a fourth grade level, this book has dramatic full-color photos of eruptions such as Mount St. Helens help show how volcanoes are created, different kinds of eruptions and cone formations, and why tsunamis often follow. ISBN 0865058385 Volcanoes in Human History: The Far-Reaching Effects of Major Eruptions Jelle Zeilinga de Boer. Princeton University Press, 2004. The book covers nine volcanic systems, their eruptions and the resulting historical fallout: The Hawaiian Islands, Thera, Mou nt Vesuvius, Iceland, Mount Tambora, Krakatau, Mount Pelee, Tristan da Cunha, and Mount St. Helens. ISBN 0691118388 Dangerous Planet: Natural Disasters That Changed History Bryn Barnard. Princeton University Press, 2004. This text describes each occurrence and discusses how the course of history was affected by it, and to what degree. Events range from the devastating asteroid impact some 65 million years ago to the kamikaze winds that foiled invasions of Japan in 1274 and 1281 and the apocalyptic storm that staggered Edward III's army on the fields of France in 1360. Colorful illustrations, many full page, accompany the text, which ends with the what-if effects of global warming. ISBN 0375822496 Hurricanes, Tsunamis, and Other Natural Disasters Andrew Langley. Kingfisher, 2006. In a largely pictorial style, this volume covers the causes and impacts of natural disasters. Four chapters, each divided into roughly half a dozen double-page sections, cover earthquakes and tsunamis; volcanoes; storms, floods, and snow; and droughts, fires, and diseases. Chapters all end with a half-page summary of the main ideas as well as short lists of print and Web resources, definitions, and places to go for exhibits. ISBN 0753459752 Hurricane & Tornado Volcanoes & Earthquakes DK Publishing, 2004. DK Publishing, 2004. Both of these DK Eyewitness books contain the gorgeous graphics and outstanding design that characterize this series. As usual, coverage is primarily visual, with brief introductory text and informative captions. The account starts with an overall perspective showing how volcanoes and earthquakes occur, with related events like steam vents and boiling mud. Effects on humans and attempts to measure and predict these events are treated. Hurricanes & Tornado ISBN 075660690X, Volcanoes & Earthquakes ISBN 0756607353 Natural Hazards: Earth's Processes as Hazards, Disasters, and Catastrophes Edward A. Keller. Prentice Hall, 2007. This book is an excellent source for Earth science information about hazardous Earth processes which affect virtually everyone living on this planet. Interesting and well-written, this book includes broad coverage of many natural hazards, including earthquakes, volcanoes, flooding, landslides, coastal erosion, extreme weather, and wildfires. ISBN 0130309575 The Great Earthquake and Firestorms of 1906: How San Francisco Nearly Destroyed Itself Philip Fradkin. University of California Press, 2006 The earthquake and fires that decimated San Francisco in April, 1906, constitute this country's worst urban catastrophe to da te. More than five hundred city blocks were flattened or burned. Fradkin's account starts out as an environmental history but evolves into a parable about human response to cataclysm. ISBN 0520248201 Earthquakes in Human History: The Far-Reaching Effects of Seismic Disruptions Jelle Zeilinga de Boer. Princeton University Press, 2007. Earthquakes in Human History provides us with evidence that natural phenomena, in this case earthquakes, can sometimes have long-term historical consequences in changing the fate of cultures. With examples ranging from biblical to modern times, they show how destructive earthquakes have interacted with wars, religious beliefs, and political movements in changing history. ISBN 0691127867 Reviews courtesy of Amazon.com CATASTROPHIC EVENTS REFERENCES TEACHER GUIDE GRADE 7 Teaching Guide How Volcanoes Work -- http://www.geology.sdsu.edu/how_volcanoes_work - This site is sponsored by NASA and explains the science behind volcanoes and the volcanic process. Natural Disasters - http://library.thinkquest.org/16132/frames.html - This ThinkQuest site allows students to work through a series of activities to develop an understanding of earthquakes, volcanoes hurricanes, tsunamis, and drought. The Disaster Area - http://www.fema.gov/kids/dizarea.htm - This FEMA site separates fact from fiction about nine different disasters including tornadoes, earthquakes, hurricanes, flash floods and thunderstorms. It also has a section on preparing for each of these potential disasters. Faultline - http://www.exploratorium.edu/faultline/index.html - This site from Exploratorium looks closely at the 1906 San Francisco Earthquake. It also discusses what, if anything, scientists have learned since then about the causes of Earthquakes and damage control. Incorporated Research Institutions for Seismology - www.iris.edu - This site includes scientific research and background information for teachers and students, as well as posters and activities for the teacher to use in the classroom. CATASTROPHIC EVENTS TEACHER GUIDE MATERIALS LIST Optional □ □ □ □ □ Red hot candy Marshmallow (large) Melted chocolate Toothpick Small sheet of wax paper Engage For each group: □ Heavy metal pan □ Sand □ Water □ Smooth brick □ Rubber mallet Explore For teacher: □ Dangerous Planet: Natural Disasters That Changed History For each group: □ Internet access Explain For each group: □ Chart paper □ Markers Elaborate For each group: □ 1 box of sugar cubes □ Metric ruler □ 2 shallow cardboard boxes □ 1 Pair of scissors □ 10-20 marbles □ 4 short rubber bands □ Stapler or tape □ Graph paper GRADE 7 Teaching Guide Student Pages CATASTROPHIC EVENT Topic Date of occurrence: Description of event: Measurement of event: Damage caused: Death toll: Other information: Source: Summary of findings: WHOSE FAULT IS IT? Look at the picture above. During this 1999 earthquake in Golcuk, Turkey, (which registered a magnitude of 7.4 on the Richter Scale) nearly 40,000 people died, and more than 130,000 were injured. Thousands of homes and utilities were destroyed in a 250 square kilometer area. Very modern buildings were totally destroyed, while the very old mosque pictured above, which was likely built around 1400, during the Ottoman Empire, was virtually undamaged. According to investigators, this mosque, like many other buildings constructed during this time period, remained intact because of their structure. Why do some buildings survive while others fall to the ground? In this activity you and your group will test different building designs to see if you can create a model that will survive the stress of an earthquake. First, you will need to build a shake tray to simulate an earthquake. Then, your group will work together to develop an “earthquake-proof” structure that can stand the force of your simulated earthquake. Good Luck. Build a shake tray 1. Place one cardboard box on a table and, with the scissors, cut the bottom out of the second box so that it fits inside the first box with a 2-cm clearance around each side. 2. Place the marbles in the first box and rest the cut piece of cardboard on top of them. 3. Use the stapler to attach one rubber band to each inside corners of the first box and then to the corners of the cardboard insert. The rubber bands should be taut, but not overstretched. 4. To start the tray shaking, pull the insert toward one side of the box and let it go. Create an earthquake-proof building 1. Using the sugar cubes as building elements, assemble several structures that each measure at least two sugar cubes high. Each structure must be different. You must have space inside of your structure that would represent the space people would use. Illustrate each of your structures on your graph paper. 2. Mark the center of the shake tray with a “X” to represent the epicenter. Place the structure on the shake tray an equal distance from the epicenter. Shake the tray to see how they stand up to your quake. Record the order in which the buildings fell. 3. Hold a design competition with your friends. See who can build an earthquake-proof structure using the most materials.
