Plate Tectonics - 2005 South Carolina Science PDF
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2005
South Carolina Department of Education
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This document is a set of lecture notes or study material on Plate Tectonics, specifically designed to meet the 2005 South Carolina Department of Education Science Academic Standards. The material covers the fundamentals of plate tectonics, including the different types of plate boundaries, volcanoes, and mountain building.
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Plate Tectonics Designed to meet South Carolina Department of Education 2005 Science Academic Standards Table of Contents Plate Tectonics: The Beginning (slides 3 and 4) Layers of the Earth (slides 5 and 6) Standard 8-3.1 What are Tectonic Pl...
Plate Tectonics Designed to meet South Carolina Department of Education 2005 Science Academic Standards Table of Contents Plate Tectonics: The Beginning (slides 3 and 4) Layers of the Earth (slides 5 and 6) Standard 8-3.1 What are Tectonic Plates- movement? (slides 7 and 8) Standard 8-3.6 Tectonic Plate boundaries (slides 9-21) 1. Convergent boundary Ocean-continent (slide 10) Continent-continent (slide 11) Oceanic-oceanic (slide 12) Volcanism (slide 13) 2. Divergent boundary Sea-floor spreading (slide 14) The Mid-Atlantic Ridge (slide 15) Sea-floor Exploration and Age Dating (slides 16-19) 3. Transform Boundary (San Andreas Fault, J. Tuzo Wilson) (slide 21) Faults (slides 22-24) and Folds (slide 25) Plate movement over Geologic Time (slides 26-29) Creation and change of Landforms (slides 30-33) Standard 8-3.7 Volcanic eruptions (Mt. St. Helens) (slide 32) Mountain building events (Appalachian vs. Himalayas) (slide 33) Tectonics and the Ocean Floor (slide 34) Standard 5-3.2 Continental margins (slide 35) Passive (slide 36) Active (slide 37) South Carolina Standards (slides 39-40) 2 Plate Tectonics: The Beginning Background At the beginning of the 20th Century, scientists realized that that they could not explain many of the Earth‘s structures and processes with a single theory. Many scientific hypotheses were developed to try and support the conflicting observations. One hypotheses was continental drift, which was proposed by Alfred Wegener in a series of papers from 1910 to 1928. The principal thought of continental drift theory is that the continents are situated on slabs of rock, or plates, and they have drifted across the surface of the Earth over time; however, originally, they were all joined together as a huge super-continent at one time. In the 1960‘s, the theory of continental drift was combined with the theory of sea-floor spreading to Alfred Lothar Wegener create the theory of plate tectonics. (1880-1930) (Photograph courtesy of the Alfred Wegener Institute for Polar and Marine Research, Bremerhaven, Germany.) Table of Contents 3 Plate Tectonics: The Beginning The idea for Wegener's theory was sparked by his observation of the nearly perfect “fit” of the South American and African continents. The “fit” of two continents. Additional evidence supporting the continental drift theory: 1. Fossils of the same plant (Glossopteris) found in Australia, India, Antarctica and South America. 2. Fossils of same reptile (Mesosaurus) found in Africa and South America. This animal could not have swum across the existing Atlantic Ocean! 3. Glacial deposits found in current warm climates and warm climate plant fossils found in what is now the Arctic. 4. Nearly identical rock formations found on the east coast of U.S. and the west coast of Europe 4 and eastern South America and western Africa. Table of Contents What are Tectonic Plates? Standard 8-3.1 The Earth is made up of three main layers: 1. The Core is at the center of the Earth. It is divided into an inner and outer core. 2. The Mantle is the layer surrounding the core. The upper mantle is partially molten and called the asthenosphere. 3. The Crust, or lithosphere, is the rigid outer-most layer. Thick continental crust underlies continents, and thin, very dense oceanic crust underlies oceans. The layers of the earth. Modified after Plummer/McGeary, 7th ed., pg. 14 Table of Contents 5 Inner Core Outer Core Mantle Crust Thickness 1,216 km 2,270 km 2,900 km Continental 35-90 km Oceanic 7-8 km Physical Solid Iron; Molten Iron, Made mostly of silicates of Made of silicate rocks Properties extremely very dense magnesium and iron; moderately and oxides; slightly dense (17 (12 g/cm3) dense. Behaves like melted plastic dense; rigid. (2.67-3.3 g/cm3) in upper-most section (5.5 g/cm3) g/cm3) Percentage of 30% 65% 5% Earths’ Mass Standard 8-3.1 What are Tectonic Plates? (continued) Earth’s Sublayers Lithosphere: This layer combines the rigid crust plus the upper-most mantle. (Greek: Rock) Asthenosphere: Partially molten part of upper mantle (Greek: weak). Tectonic plates are able to move about on top of the softer, partially molten asthenosphere. The outer- most layers of the earth. McGraw Hill/ Glencoe, 1st ed., pg. 142. 6 Table of Contents Standard 8-3.6 What are Tectonic Plates? (continued) The Earth‘s crust consists of about a dozen large slabs of rock, or PLATES, that the continents and oceans rest on. These tectonic plates can move centimeters per year— about as fast as your fingernails grow up to 15cm/yr in some places. Tectonic plates are also called lithospheric plates because the crust and the upper-most mantle make up a sub-layer of the earth called the lithosphere. The plates can move about because the uppermost mantle, or the asthenosphere, is partially molten and possesses a physical property called plasticity, allowing the strong, rigid plates of the crust to move over the weaker, softer asthenosphere. Plates and relative plate motion. Modified after NOAA South Carolina is located on the North American plate The word TECTONICS is of Greek origin and it means ―to build.‖ The word ―tectonism‖ refers to the deformation of the lithosphere. This deformation most notably includes mountain building. 7 Table of Contents Standard 8-3.6 What are Tectonic Plates? (continued) Tectonic plates, or lithospheric plates, are constantly moving, being created, and consumed simultaneously. The motion sometimes results in earthquakes, volcanoes, and mountain ranges at the plate boundaries. Plate motion is driven by heat escaping from the mantle. The constant movement of heat in the mantle leads to circular convection currents. These hot convective cells are similar to the rolling boil that occurs when water is heated on a stovetop. The flowing mantle has also been compared to a ―conveyor belt,‖ moving the rigid plates in different directions. Fundamentally, convection occurs due to uneven heating and different densities within the liquid. Spreading ridge Subduction zone Upwelling Downwelling = Core Convection currents within the mantle. Modified after Plummer/McGeary, 7th ed., pg. 15 8 Table of Contents Plate Boundaries There are three basic ways that plates interact with one another. Each of these plate boundaries has the potential to create different geological features. 1. When plates collide with each other = Convergent boundary 2. When plates separate from each other = Divergent boundary 3. When plates slide along side each other = Transform boundary The tectonic plates and plate boundaries. McGraw Hill/Glencoe, 1st ed., pg 143 Table of Contents 9 1. Convergent Boundary: Ocean-Continent Collision Because the oceanic crust is more dense than continental crust, when these two collide, the continental crust rides up over the oceanic crust and the oceanic crust is bent down and subducted beneath the continental crust. This is called a subduction zone, where the old oceanic crust is dragged downward and ―recycled.‖ Deep-sea trenches are created at subduction zones. Trenches are narrow, deep troughs parallel to the edge of a continent or island arc. They typically have slopes of 4-5 degrees, and they are often 8-10 km deep. The deepest spots on earth are found in oceanic trenches. The Mariana Trench is the deepest ocean depth at 11 km (35,798 ft) below sea level. Figure depicting oceanic crust subducting beneath continental crust, creating volcanoes on the land surface above, and a deep- sea trench off of the coast. Credit: U.S. Geological Survey Department of the Interior/USGS 10 Table of Contents Convergent Boundary: Continent-Continent Collision If two continental plates collide, mountain building usually takes place because they are both relatively low in density. Earthquake activity at these boundaries is common; however, because igneous activity is different from ocean-continent collisions, volcanoes are rare. Examples: The Himalayan and the Appalachian mountain chains. Constructive mountain building during continent-continent collision. The Himalaya McGraw Hill/Glencoe, 1st ed., pg 149 mountains are still forming today as the Ind-Australian Plate collides with the Eurasian Plate 11 Table of Contents Convergent Boundary: Ocean-Ocean Collision If 2 oceanic plates collide, the older, denser one is subducted downward into the mantle and a chain of volcanic islands can form, called a volcanic arc. Example: Mariana Islands (Mariana Trench). It is deeper than the earth‘s tallest mountain is tall. Mariana Trench: 11,000 meters deep. Mt. Everest: 8850 meters high. The interaction of the descending oceanic plate causes incredible amounts of stress between the plates. This usually causes frequent earthquakes along the top of the descending plate known as the ―Benioff Zone.‖ The focii of Benioff earthquakes can be as deep as 700 km below sea level. Oceanic/oceanic collision resulting in a chain of island arcs. Credit: U.S. Geological Survey Department of the Interior/USGS Benioff Zone 12 Table of Contents Convergent Boundary: Volcanism Most volcanoes form above subduction zones because as one slab is subducted beneath the other, the interaction of fluids and geothermal heat form new magma. The new magma then rises upward through the overlying plate to create volcanoes at the surface. The Andes Mountains are home to many volcanoes that were formed at the convergent boundary of the Nazca and South American Plates. Left: Image of the Nazca Plate subducting beneath the South American Plate. Modified after McGraw Hill/Glencoe, 1st ed., pg. 143 Right: Red dots indicate general locations of volcanoes along western coast of South America. 13 Table of Contents 2. Divergent Boundary: Sea-floor Spreading At a divergent boundary, two oceanic plates pull apart from each other through a process called sea-floor spreading. Sea-floor spreading was proposed by Harry Hess in the early 1960‘s. Hess proposed that hot magma rises from the asthenosphere and up into existing ocean crust through fractures. The crust spreads apart making room for new magma to flow up through it. The magma cools, forming new sea floor and resulting in a build-up of basaltic rock around the crack, which is called a mid-ocean ridge. Sea-floor spreading at an oceanic divergent boundary. Modified after McGraw Hill/ Glencoe, 1st ed., pg. 138 (with permission) New material is constantly being created. This is the opposite of a convergent boundary, where material is constantly being destroyed. Table of Contents 14 Divergent Boundary: Mid-Atlantic Ridge The world‘s longest mountain chain is underwater. It is 56,000 km long and is called the Mid-Atlantic Ridge. The Mid-Atlantic Ridge is considered a slow-spreading ridge, spreading at about 1-2 centimeters per year. An example of a fast-spreading ridge is the East Pacific Rise, which spreads at about 6-8 centimeters per year. Satellite bathymetry of the East Modified after http://www.ocean.udel.edu/deepsea/level- 2/geology/ridge.html Pacific Rise spreading ridge. Credit: U.S. Geological Survey 15 Table of Contents Department of the Interior/USGS Sea-floor Exploration The Deep Sea Drilling Project (DSDP) began in 1968 aboard the research vessel Glomar Challenger. This ship was outfitted with a drill rig capable of drilling into the ocean floor beneath many kilometers of water. Before this type of research was available, scientists had to rely on dredging or grabbing single rock samples from line weights on boats. Scientists quickly determined that continental crust is thicker than oceanic crust, that continental crust is less dense than oceanic crust, and that the youngest seafloor is located at mid-ocean ridges and increases in age with distance from the ridge. Before technology like this, most people thought the ocean floor was flat and smooth. This is understandable as 2/3 of the Earth‘s surface lies under oceans. The Glomar Challenger (1968) Credit: U.S. Geological Survey Department of the Interior/USGS 16 Table of Contents Sea-floor Exploration In the mid-1960‘s, magnetometer surveys at sea indicated that alternating magnetic anomalies existed within marine rock. These anomalies were aligned parallel to the Mid-Atlantic Ridge forming stripe-like patterns on the sea floor, and they were symmetrically distributed on either side of the Mid-Atlantic Ridge. Geologists Fred Vine and Drummond Matthews first noticed these symmetric patterns of magnetic ―stripes‖ and concluded that this pattern of magnetic anomalies at sea matched the pattern of magnetic reversals over time. The Earth‘s magnetic field flows from a southerly direction to northerly direction. This is what makes the arrow on our compasses point towards north. The Earth‘s magnetic field has changed over the past 100 million years approximately once every 250,000 years. When the magnetic field ―reverses‖ from today‘s ―normal‖ N-S direction it becomes a period of magnetic reversal. The normal magnetic field is considered a positive anomaly, and, when the magnetic field is reversed, it is considered a negative anomaly. 17 Table of Contents Sea-floor Exploration: Age-dating The relative age of the sea floor T1 can be determined by changes in T2 magnetic polarities of the earth. Oldest T3 These periods of normal and Youngest reversed polarity are recorded in the magnetic minerals within the newly formed sea floor at mid-ocean ridges. Scientists can see a clear pattern of normal and reversed magnetization in the rock record Above: Figure depicting magma flowing out that shows up as ―magnetic stripes‖ from a spreading ridge, cooling and spreading on either side of mid-ocean ridges, out symmetrically about the ridge to produce which gives them a relative time of successively older rock as you travel in either direction from the ridge. The magnetized how old the sea floor is and lets minerals within the rock ―tell‖ how old it is. them compare ocean basins to each Credit: U.S. Geological Survey other. Department of the Interior/USGS Table of Contents 18 Sea-floor Exploration: Age-dating The oldest oceanic crust found is ~ 180 million years old. Because the age of the earth is ~4,600 million years, we know that oceanic crust is continually being formed at spreading ridges and being destroyed at subduction zones. The ocean floor is constantly changing shape and size through the processes of sea-floor spreading and subduction. Because no older ocean crust has been found, recycling of the ocean crust takes place about every 180 million years. The relative ages of the ocean floor. Credit: Nova. Table of Contents 19 3. Transform Boundary When two plates slide past each other moving in different directions or the same direction, it is termed a transform boundary and is characterized by a transform fault and earthquake activity. An example of a transform fault is the San Andreas Fault in California. Here the North American Plate joins the Pacific Plate. The difference in plate motion along the contact (fault) leads to a buildup of strain energy that sometimes slips releasing a huge amount of energy and causing an earthquake. An aerial photo of the San Andreas Movement between the 2 plates at the San Andreas fault line. McGraw Hill/Glencoe, 1st ed., pg. 146 Transform Fault. McGraw Hill/Glencoe, 1st ed., pg. 146 (with (with permission) permission). Table of Contents 20 Transform Boundary (continued) J. Tuzo Wilson was a geophysicist who was fascinated by Wegener's theory of continental drifting. He was also inspired by Harry Hess, whom he studied under at Princeton University in the 1930‘s. Wilson is recognized today for advancing plate-tectonic theory by introducing three major concepts: 1. Wilson (1963) introduced the concept of a ―stationary hotspot‖, where the heat from the mantle could affect the thin crust, forming volcanic islands such as Hawaii. 2. Wilson (1965) proposed the ―transform‖ boundary as the third type of plate boundary. They commonly offset ocean ridges and trenches, and transform the motion between the offset. Unlike ridges and trenches, transform faults offset the crust horizontally, without creating or destroying crust. 3. Wilson proposed what is known today as the Wilson Cycle. This concept explains the origin for the Appalachian Mountains. The ―cycle‖ goes through the sequence: 1. The splitting of a supercontinent, 2. the opening of an ocean basin, 3. the closing of the ocean basin, 4. the collision of continents and formation of mountains. 21 Table of Contents Mountain building processes, faults and folds Plate tectonics cause many of the physical features that we see on earth today like volcanoes and earthquakes, but also many other geological features like faults. Faults are planar rock fractures along which movement has occurred. A transform fault occurs at a transform plate boundary like the San Andreas Fault in California. It connects two of the other plate boundaries. Similar in movement, a strike-slip fault occurs through shearing when two blocks move in horizontal but opposite directions of each other. Depending on the direction of offset, it can be a Right-lateral offset ―right-lateral offset‖ or a ―left-lateral offset.‖ In the example above, it is obvious that the fence The photograph above displays a light-colored has been offset to the right, therefore it is called a pegmatite vein offset to the right in a schistose right lateral strike-slip fault (Credit: U.S. Geological matrix. Photo courtesy of K. McCarney-Castle. 22 Survey Department of the Interior/USGS) Table of Contents Faults: Normal Faults Faults caused by blocks of crust pulling apart under the forces of tension are called normal faults. Entire mountain ranges can form through these processes and are known as fault block mountains (examples: Basin and Range Province, Tetons). In a normal fault, the hanging-wall block moves down relative to the foot-wall block. The footwall is the underlying surface of an inclined fault plane. The hanging wall is the overlying surface of an inclined fault plane. Hanging wall block Footwall block Hanging Wall Foot Wall Relative movement of two blocks Diagrammatic sketch of the two types of blocks used in identifying normal faults. indicating a normal fault. (Credit: Modified after 23 U.S. Geological Survey Department of the Interior/USGS) Table of Contents Faults: Reverse Faults Faults caused by blocks of crust colliding under the forces of compression are called reverse faults. Reverse faults form during continent-continent collision. Usually, there is also accompanying folding of rocks. During reverse faulting, the hanging wall block moves upward (and over) relative to the footwall block. Hanging wall block Footwall block Hanging Wall Foot Wall Diagrammatic sketch of the two Relative movement of two blocks types of blocks used in identifying indicating a reverse fault. (Credit: U.S. Geological reverse faults. Survey Department of the Interior/USGS) 24 Table of Contents Folding During mountain building processes, rocks can undergo folding as well as faulting. Sometimes rocks deform ductilely, particularly if they are subjected to heat and pressure. At elevated temperature and pressure within the crust, folds can form from compressional forces. Entire mountain rages, like the Appalachians, have extensive fold systems. Z-fold in schist with white felsic dike Large fold in outcrop (geologists for scale). (hammer for scale). Near Lake Murray, Near Oakridge, Tennessee, Appalachian South Carolina. Mtns. Photo courtesy of K. McCarney-Castle. 25 Photo courtesy of K. McCarney-Castle Table of Contents Plate Movement Over Geologic Time Alfred Wegener proposed that all of the continents once formed a ―supercontinent‖ called Pangaea. From the Greek language, ‗pan’ meaning ALL and ‗gaea’ meaning EARTH. It was thought to have come together and formed approximately 200 million years ago. Evidence for a supercontinent included: 1. Fossils of the same plant (Glossopteris) found in Australia, India, Antarctica, and South America. 2. Fossils of same reptile (Mesosaurus) found in Africa and South America. This animal could not have swum across the existing Atlantic Ocean! 3. Glacial deposits found in current warm climates and warm-climate plant fossils found in what is now the Arctic. 4. Nearly identical rock formations found on the east coast of U.S. and the west coast of Europe and on eastern South America and western Africa. 26 Table of Contents 1. About 1,100 million years ago, a super- continent called Rodinia existed (pre- Cambrian). 2. Rodinia broke apart, and about 400 million years ago, the oceans began to close up to form a pre-Pangea (early Devonian). Table of Contents 27 3. Pangea formed around 250 million years ago and animals could migrate from the north to the south pole (Early Triassic). PaleoMaps used with permission from Christopher Scotese and are under copyright of C.R. Scotese, 2002 4. Pangaea began to break apart into 2 halves approximately 200 million years ago (Early Jurassic). The northern half is called Laurasia and the southern half is called Gondwanaland. These two huge continents were separated by a body of water called the Tethys Sea. 5. Gondwananland split to form Africa, South America, Antarctica, Australia and India. Laurasia split to form North America, Eurasia (minus India) and Greenland. 6. Around 15 million years ago, the continents finally looked like they do today PaleoMaps used with permission from Christopher Scotese and are under copyright of C.R. Scotese, 2002 Table of Contents 28 Continents in the future? In 50 million years, it is possible that the Mediterranean could close due to the collision of Africa with Europe. Australia may eventually join Asia. Table of Contents 29 It is though that in another 250 million years, another Pangea will form. PaleoMaps used with permission from Christopher 29 Scotese and are under copyright of C.R. Scotese, 2002 Standard 8-3.7 Creation and Change of Landforms Volcanoes Most volcanoes form above subduction zones because as one slab is subducted beneath the other, it causes melting, forming new magma, which then rises upward. This is why most volcanoes are found near plate boundaries. Volcanoes are constructive because they add new rock, form new islands, and create new land masses. However, they are also destructive when they erupt and change the landscape (possibly even the climate). Above: Diagrammatic sketch of a volcanic arc located above a subduction zone Left: Active volcanoes found along plate boundaries (Credit: U.S. Geological Survey Department of the Interior/USGS) 30 Table of Contents Volcanic Eruptions: Most volcanoes form above subduction zones because as one slab is subducted beneath the other, melting occurs, forming new magma, which then rises upward along the plate boundary. Being hot, magma is less dense than the solid rock surrounding it. This enables the liquid magma to rise up through cracks in the solid rock and collect in pockets within the earth, called magma chambers. Eventually some of the magma pushes through vents and fissures in Earth's surface, causing an eruption that may be violent or quiet. Once the magma reaches the earth‘s surface, it is called lava. The explosiveness of an eruption depends on the viscosity of the magma. Viscosity is the resistance of a liquid to flow. If the magma is very thick and viscous, gases can build up within the magma. Finally, when threshold is reached, there is a violent eruption from the built up pressure of the gases in the magma chamber. If magma is less viscous, or more fluid, gases Vent Volcano can escape easily from it. When this type of magma erupts, it flows out of the volcano and Magma chamber violent explosions are rare. Land Sometimes, huge clouds of ash race down surface mountainsides destroying almost everything in Crust their path. These are pyroclastic clouds. They Upper mantle can travel faster than a high-speed train. The ash produced from an eruption will fall back to the Lower mantle ground and suffocate humans, animals, and Core plants. Cross-sectional view looking through 31 the side of a volcano Table of Contents Volcanoes: Mount St. Helens A famous volcano that erupted in the U.S. nearly 30 years ago was Mt. St. Helens in the Cascade Range of Washington. The volcanic activity of Mt. St. Helens is caused by the ongoing subduction of the Juan de Fuca plate under the North American plate. It is part of the Cascade Volcanic arc, which includes some 160 active volcanoes along the west coast. On May 18, 1980 Mount St. Helens erupted in what was the most economically destructive volcanic event in U.S. history. Nearly 60 people lost their lives and 250 homes were destroyed. Before the volcano exploded, it was 2,950 m tall. Afterwards, it was 2,550 m tall, and instead of a sharp peak at the summit, a mile-wide horseshoe shaped crater was left. The debris avalanche associated with the eruption was nearly 3 cubic kilometers in volume. When Mount St. Helens exploded, it had not erupted for 123 years. Most people thought Mount St. Helens was a beautiful, peaceful mountain and not a dangerous volcano. Before eruption… After eruption… 32 Table of Contents Credit: Wikimedia Commons Mountain-building forces When two continental plates collide at a convergent boundary, the process produces a mountain range. Compressional forces drive the mountain building process. The Appalachians, the Alps, and the Himalayas were formed through compression. The Himalayan mountain chain was formed Continent/ approximately 150 million years ago. When we continent convergence think of the Himalayas, we think of very high, steep mountains, cliffs, and, of course, Mt. Everest. The Matterhorn, Alps In contrast, when we consider our own Appalachians, which formed about 400 million years ago, we see more subdued topography than in the Himalayas. This is because the process of wind and water erosion have eroded hundreds of vertical feet of land surface from the area and reduced high jagged mountains into the rolling The Appalachian Mountains. Photo courtesy of K. McCarney-Castle hills present today. 33 Table of Contents Standard 5-3.2 Continental margins and deep-sea landforms Even though approximately 70% of the earth‘s surface is covered by water, it is the study of sea- floor rocks, sediment, and topography that provide most of the information used to validate the theory of plate tectonics. Ongoing research on the sea floor continues to provide clues to the Earth‘s dynamic structural processes. Research and technology have granted us access to study both the shallow continental shelves as well as the deep abyssal plains of the ocean basins. These include rock dredging, coring, drilling, geophysical studies (seismic and magnetic), and age dating. One advancement in technology is the use echo sounders, which are used to draw profiles of submarine topography. Seismic profilers also use acoustic echoes but can penetrate the bottom of the seafloor. These profilers allow us to see a ―picture‖ of the layered structure under the sea floor. Africa, west USA, west USA, east coast coast coast Cross-sectional view of continents grading into Continent deep ocean basins. Note change in topography. Ocean Basin 34 Table of Contents Continental Margins: Continental Shelves and Slopes All continents are surrounded by a shallow, relatively flat platform called a continental shelf and a sloping surface called a continental slope that gently descends down to the deep ocean floor. Continental shelves vary in width depending on the type of continental margin. On the U.S. Pacific coast, it is only a few km wide, but off of the Atlantic Coast it is up to 500 km wide. The continental shelf area has thick accumulations of young sediment and has water depths less than 200 meters. The continental slope has a relatively steep slope (4-5 degrees) and it joins the edge of the shelf to the deep ocean floor. Relatively little is known about the slopes, as it is difficult to drill on the steep surfaces. Beyond the continental shelf is the continental break where flat shelf ends and the steep continental slope begins. Although typical continental slopes have an incline of around 4 degrees, some active margins, like the Gulf of California, slope at about 20 degrees. The continental slope may be marked by channels called submarine canyons that transport sediment from the shelf to the sea floor, sometimes in violent events called turbidity currents. The continental rise has been built up by these thick deposits of sediment. California Continental Margin looking east towards Los Angeles. Shelf (Credit: U.S. Geological Survey Slope Department of the Interior/USGS) Table of Contents 35 1. Passive Continental Margins A passive continental margin includes a continental shelf, slope, and rise and these margins gently grade into a deep abyssal plain. The ocean floor and continent usually belong to the same continental plate. Passive margins form on ―geologically quiet‖ coasts, also called trailing margins, where there is no tectonic or volcanic activity, such as the eastern seaboard of the U.S. The continental rise is a wedge of sediment that extends from the lower part of the slope to the deep sea floor sloping at about 0.5 degrees. It grades into a flat abyssal plain at around 5km in depth. Abyssal plains are found at the base of the continental rise and are the flattest features on earth. Abyssal plains form where turbidity currents carry amounts of sediment large enough to bury and obscure the rugged relief normal found on the sea floor. Continental break Sketch of an abyssal fan forming on the sea floor. Sediment for the fan is carried from the shelf through the canyon in violent turbidity currents and are deposited, forming a fan. Continental Slope Modified after Plummer/McGeary, 7th ed., pg. 400. Table of Contents 36 Active continental Passive continental margin with trench margin Cross-sectional sketch showing the trench off the active continental margin and the rise off of the passive continental margin. 2. Active continental margin: An active continental margin includes a continental shelf, slope, and an ocean trench. It is the result of an ocean plate colliding with a continental plate. Active margins are tectonically active, characterized by earthquakes, volcanoes, and mountain belts. Tectonically active margins may have a deep trench instead of a continental rise where the oceanic plate is subducted beneath the continental plate. The west coast of the U.S. and South America are examples of active margins. Ocean trenches are elongate features parallel to the edge of the continent and are the deepest regions on earth at over 11 km below sea level. Ocean trenches are associated with seismic Benioff Zones, which begin at the trench and dip underneath the continent as part of the subduction zone. Earthquakes are prevalent along the Benioff Zone, which is the site of one tectonic plate descending underneath another. Table of Contents 37 Satellite bathymetry of the East Pacific Rise spreading ridge. Credit: U.S. Geological Survey Sea floor spreading at the mid-ocean ridge Department of the Interior/USGS and rift valley. Modified after McGraw Hill/ Glencoe, 1st ed., pg. 138 (with permission) The Mid-Atlantic Ridge is an example of a divergent boundary found extending around the world dividing the world‘s ocean basins. It spreads at about 1-2 centimeters per year and is made of basalt. It is 56,000 km long and 2,500 km wide, and it rises 2 –3 km above the sea floor. The spreading of the ridge creates a rift valley running down the crest of the ridge. The valley is about 1-2 km deep and several kilometers wide- similar to the dimensions of the Grand Canyon! Shallow earthquakes are frequent along these ridges and long deep fractures run perpendicular to the ridge. Seamounts, guyots, and black smokers are other geological features that can be found on the deep sea floor. Table of Contents 38 South Carolina Science Academic Standards: Grade 5 1) Landforms and Oceans Standard 5-3: The student will demonstrate an understanding of features, processes, and changes in Earth‘s land and oceans. (Earth Science) Indicators: 5-3.2: Illustrate the geologic landforms of the ocean floor (including the continental shelf and slope, the mid-ocean ridge, rift zone, trench, and the ocean basin). Table of Contents 39 South Carolina Science Academic Standards: Grade 8 1) Earth’s Structure and Processes: Standard 8-3: The student will demonstrate an understanding of materials that determine the structure of the Earth and the processes that have altered this structure. Indicators: 8-3.1: Summarize the three layers of Earth—crust, mantle, and core—on the basis of relative position, density, and composition. 8-3.6: Explain how the theory of plate tectonics accounts for the motion of the lithospheric plates, the geologic activities at the plate boundaries, and the changes in landform areas over geologic time. 8-3.7: Illustrate the creation and changing of landforms that have occurred through geologic processes (including volcanic eruptions and mountain-building forces). Table of Contents 40