Rocks Avalanches Volcanoes Impact on lithosphere of Earthquakes Plate tectonics weathering and erosion Landslides mining, deforestation, overgrazing, agriculture, urbanization, and conventional and sustainable agriculture. Details of the rock cycle related to cycling of materials Formation and destruction of the three basic rock types to the forces responsible Physical and chemical weathering Heat and pressure Depositon Foliation and bedding Forms of energy that drive the rock cycle Heat and mechanical (gravitational potential) energy Bellringer What are the three major types of rocks? How are each type formed? Igneous – cooling of molten magma Sedimentary – weathering, erosion, deposition, and lithification Metamorphic – heat and pressure www.sasinschool.com Username: wlincoln QL # 71 59 – 98 49-82 58-97 48-80 57-95 47-78 56-93 46-77 55-92 45-75 54-90 44-73 53 –88 43-72 52 - 87 42-70 51 - 85 41-68 50 - 83 40-67 Type of Rock Igneous Sedimentary Metamorphic How is this rock formed? List three 1. Examples: 2. 3. 1. How does the formation of extrusive igneous rock differ from that of intrusive igneous rock? 2. Compare and contrast the composition of the three different kinds of sedimentary rocks. 3. What are the characteristics of foliated and non-foliated metamorphic rocks? intrusive igneous rock extrusive igneous rock – - magma cools inside rapid cooling of lava or crust, magma enters or melted rock on the intrudes into other earth’s surface rock masses below the earth’s surface forming intrusive - size of crystalline grains in igneous rock and is largely determined by the cooling rate of the magma or lava that formed the rock • Coarse grained – well developed grains crystalline • Fine grained – rapid cooling causing small • • • crystalline grains Porphyry – mixture of fine and coarse grained Glassy – crystals unable to form Pumice – bubbles formed in rock due to extreme rapid cooling which traps gases Basaltic – low silica Andesitic – intermediate levels of silica Rhyolitic – high silica Felsic – light colored with high silica content Mafic – dark colored, low silica content rich in Fe and Mg Ultramafic – low silica and very high levels of FE and Mg p. 108 based on mineral composition and texture Intrusions and Extrusions http://www.minsocam.org/MSA/K12/rkcycle/igneousrks.htm l Made of accumulations of various types of sediment Formed by lithification – compaction and cementation Clastic – pieces or fragments of minerals pressed or cemented together Chemical – form from minerals that were once dissolved in water Organic – form from remains of living things Formed by changing of one type of rock to another by heat, pressure, and chemical processes Formed by existing igneous, sedimentary, or metamorphic rocks Foliated – wavy layers and bands Unfoliated – nonbanded appearance Read text pages 443-463 Chapter 5 Assessment p. 118 (1-16) Board game Instructions: Follow written instructions and Fill in the geologists notes each time a player moves. Answer questions on the back of the geologist notes. Weathering of rocks creates soil Sand Silt clay When rocks are broken down into smaller pieces Temperature and pressure 1. Mechanical (physical) No change in composition of rock only size and shape b. Causes 1. Temperature ex: frost wedging 2. Pressure ex: from overlying rock layer pressure becomes reduced & exfoliation occurs ex: tree roots a. 2. Chemical Rocks undergo changes in composition b. Caused by a. 1. 2. 3. 4. Water ex: hydrolysis Oxygen ex: oxidation Carbon Dioxide ex: carbonic acid Acids – ex: acid precipitation When the chemical composition changes Hydrolysis Oxidation Carbonic acid Acid rain Caused mainly by the oxidation of sulfur dioxide Acid rain has a pH below 5.6 on the pH scale Climate Rock type and composition Surface area Topography decaying of organisms How can water be an agent for physical weathering? A. By absorbing gases from the atmosphere and ground to chemically react with minerals B. By seeping into the soil and dissolving the minerals in rocks C. By absorbing sulfur oxides and creating acid precipitation D. By seeping into the cracks of rocks and freezing Cracks in rocks widen as water in them freezes and thaws. How does this affect the surface of the Earth? A It reduces the rates of soil formation. B It changes the chemical composition of the rocks. C It exposes rocks to increased rates of erosion and weathering. D It limits the exposure of rocks to acid precipitation. A. Erosion - process that transports Earth materials from 1 place 2 another B. Agents of Erosion 1. 2. Wind Water a. b. Rill gully Glaciers 4. Gravity 5. Plants, animals, and humans 3. Water Wind Ice gravity Gravity pulls everything downhill. Examples: glaciers, mud, water Moving water Glaciers Wind gravity What are the agents of erosion? Weathering is the process of breaking down rocks and erosion is the process of moving the material. II. III. IV. V. VI. VII. The purpose of this lab is to determine the effects of choose one (chemical weathering, wind erosion, or water erosion. Refer to your lab paper. In your group create a materials list. Give procedures in your notebook for your specific lab Collect data requested. Was your hypothesis correct? Why or why not? Chemical Weathering: If vinegar is added to the limestone, then the limestone will weather (more/less than when pure water was added). Water Erosion: If the mountain is supported by a dam, then there will be (more/less) water erosion. Wind Erosion: If pebbles are added to the surface of the sand, then (more/less) sand will blow away. Which agent of erosion leads to the formation of sand dunes? A. Ice B. Wind C. Water D. gravity Using a half hotdog sheet of paper, divide the paper into three sections. Describe the three major soil horizons: A, B, and C found in a soil profile. Use images to help you remember. P. 169 Weathering of rocks creates soil Sand Silt Clay A. Define: weathered materials, humus, and overlying bedrock (varies on location) B. Composition 1. 2. 3. Bedrock that weathered Residual soil – above parent rock Transported soil What are soil horizons? 2. What causes leeching? 3. What is required for crops to grow? 4. What is silt made up of? When is soil called silt? 5. What do microorganisms produce? 6. Where can inceptisols be found? 7. Where are ultisoils found? 8. What are the types of water erosion? How do they occur? 9. What are methods farmers employ? 10. Who is the understanding of soil essential to? 1. C. Profile – vertical sequence of soil layers Soil Horizon A – organic material and humus B – sub soils enriched with clay materials C – weathered parent material D. Soil types: Polar, temperate, desert, & tropical Weathered rock humus –decayed organic matter Residual soil remains on top of its parent bedrock Transported soil is moved to a new location by agents of erosion Topsoil is located in horizon A Subsoil is located in horizon B Weathered rock is located in horizon C Texture Fertility color Mollisols Organically rich with lots Great plain region, of humus prairie regions Oxisols Red in color due to leeching lots of iron spodosols High iron and aluminum, Cool or cool humid horizon b rich in organic regions material, most chemically weathered ultisols Moist, acidic well developed , red subsoil vertisols Fertile but hard to farm Alternating wet and dry because of hard texture, season deep with cracks alfisols Crops grow easily Warm tropical regions Warm humid climates Under Forests and grasslands, mild humid climate aridisols Small amts of organic material, sandy texture, light colored Dry and desert regions entisols Little development and closely resemble parent material Found in recently exposed surfaces like flood plains and sand hills histisols Acidic organic Swamps, bogs and other water saturated places that don’t drain well. inceptisols Slightly developed soils and young soils Former flood plains and stable land surfaces Read text p. 443-463 • Bellringer 4/22 • What is the name Wegener gave to the supercontinent or a single prehistoric landmass? P. 444 • Proposed the hypothesis of continental drift in 1912 • A German scientist • Wegener began to wonder how the continents were related • Is it possible the continents were all connected at one time? • Continents seemed to fit together – maybe they just split apart • Continental Drift • Hypothesis explaining movement of the continents • Continents once formed a single land mass and about 200 million years ago began breaking up into smaller continents. • Continents sit on lithospheric rock plates • Plates float on asthenosphere • Earth’s face changes as the plates continue to move http://www.ucmp.berkeley.edu/geology/tectonics.html • Continents as a single land mass • Huge ocean that surrounded pangaea • • • • Geological evidence Fossils Weather patterns Similarities in Coastlines • Fossil records • Areas that were once connected have fossils of the same plants and animals • Mesosaurus – found in eastern South America and western Africa Skeptics say this lizard-like creature could have swam from Africa to South America…. NOPE! Mesosaurus was a FRESH water animal • Geologic records • Areas that were once connected have rocks of the same age and type • Areas that were once connected have mountain chains that appear to match up • Wegner looked at evidence of ancient climates and noticed that some areas had once been covered with glaciers • Some of these areas are now in tropic regions • Wegener’s hypothesis was incomplete • It did not explain what force made the continents move • What forces cause continents to move? • How could continents move without shattering? • Shortly after Wegeners hypothesis was rejected new technology helped map the ocean floor. • Mapping the Mid-Atlantic Ridge • A mid-Atlantic ridge ran down the center of the atlantic ocean between North/South America and Africa/Europe • A crack ran down the center of this ridge • Dating the rocks • The ocean floor was younger than the continental rocks • How weird…what was going on under the water? • What if that valley was a rift? • Molten rock could well up through the crack • Both sides of the rift pull away as the molten rock comes through • Magma cooled & hardened to form new rock • Wegener’s Triumph • If the ocean floor is moving, the continents could be moving • The continents are moving an average of 5cm per year • • • • Magma solidifies to form rock Iron-rich minerals align with the earth’s magnetic field Magnetic orientation becomes permanent So, do all rocks have the same magnetic orientation? So, do all rocks have the same magnetic orientation? • Lining up with the magnetic field… • But some rocks point south • The earth’s magnetic field must have reversed itself! • Magnetic patterns on the ocean floor helped prove that the rift was pulling apart and the ocean floor was moving… …So we really are moving! • Technology that allowed for study: • Sonar • Magnetometer - detects changes in magnetic fields • Ocean ridges – mountain chains • Deep sea trenches – narrow elongated depression in sea floor with steep sides • Age of ocean rocks are younger than continental rock • Ocean sediments are thinner than continental sediments • Study of magnetic record • Normal polarity – orientation of field is same as todays • Force that causes continents to move away from both sides of the ridges and be replaced by rising magma that cooled to form new rock on ocean floor. Our Movin’ & Groovin’ Planet • What theory states that new ocean crust is formed at ocean ridges and destroyed at deep sea trenches? Wegener’s Continental Drift Hypothesis + Seafloor Spreading Hypothesis = Theory of Plate Tectonics • Theory of plate tectonics explains HOW and WHY continents move • oceanic crust – formed by materials on the ocean floor • continental crust – makes up the continental landmasses • Bellringer: • What are three mechanisms that drive the movement of the lithosphere? 460-462 • Mantle convection – transfer of thermal energy in unequally heated matter • Ridge push – weight of an elevated ridge pushes an oceanic plate towards a subduction zone • Gravity pull – weight of subducting plate helps pull the trailing lithosphere into the subduction zone (slab pull) • http://pubs.usgs.gov/publications/text/understanding.html#a nchor5567033 • Bellringer : 4/23 • What are the two layers of the Earth’s crust? What are the two types of the Earth’s crust? What are the characteristics of all four? P. 525, 422, 450, and 8 • Lithosphere • Asthenosphere • Oceanic crust • Continental crust • Upper mantle • Very hot, slowly flowing “plastic” rock Plates of the lithosphere float on the asthenosphere • About 30 plates known • Changes in the earth’s crust can be seen along plate boundaries. • Three Types of Boundaries • Divergent Boundary • Convergent Boundary • Transform Fault Boundary • Divergent – two plates moving away from each other forming a rift valley • Convergent Boundaries – collision of one plate with another due to seafloor spreading • Transform fault boundary – two plates are grinding past each other • Formed by plates moving apart • Found mostly along ocean floor but some are also on land • Rift valleys • Mid-Atlantic Ridge • Formed when plates push together • Responsible for major landforms such as mountains and volcanoes • Places where lithosphere crust is being push into the mantle are called subduction zones • Oceanic crust goes under continental crust • Subduction zone • Forms oceanic trenches • Forms volcanic mountains • Colliding edges crumple • Produce mountain ranges • Which structure can form as a result fo a divergent plate boundary? A. A continental volcanic arc, due to the collision of two plates B. A continental mountain, due to the collision of two plates C. A mid-ocean ridge, due to the separation of two plates D. An ocean trench, due to the separation of two plates • Ocean trench forms when plate is subducted • Forms island arcs 1. 2. 3. 4. 5. What type of plate boundary collides? What type of plate boundary divides? What type of plate boundary slides? What type of boundary forms volcanoes and mountains? What type of boundary creates earthquakes? I. Food Tectonics Lab II. The purpose of this lab is to describe the interactions between plate boundaries and landforms they produce. III. If the activities at the different plate boundaries is simulated, then the land formations can be determined. IV. One large graham cracker, fruit roll up, cup of water, frosting, wax paper, plastic knife or spoon V. Refer to directions given. VI. 1. 2. 3. 4. VII. 1. Data – Draw each of the 4 types of interactions between plates oceanic plate divergence continental-oceanic plate convergence continental-continental plate convergence continental-continental transform plate boundaries Conclusion What forms at each of the plate boundaries a. b. c. d. 2. 3. 4. Divergent (oceanic –oceanic) plate boundaries p.535 Convergent (continental – oceanic) plate boundaries p.530 Convergent (continental-continental) plate boundaries p. 531 Transform plate boundaries p. 546 How did the Appalachian mountain ranges form? P. 532 What does subducted mean? Was your hypothesis correct? Why or why not? • Formed where plates grind past one another • Ocean trenches • Mountain ranges • Mid-ocean ridges • How are these related to the theory of plate tectonics and geologic time • subduction zone – boundary where one plate moves under another plate oceanic moves under continental forming an ocean trench • neither is subducted due to density of plates being the same, instead they are crumpled and uplifted into mountain ranges • oceanic crust and oceanic crust, ocean trench is formed, plate melts and forms an island arc • Bellringer • Which will most likely form when movement along a plate boundary forces a landmass to be pulled apart? • A volcanic island arc • B continental mountains • C continental rift • D oceanic trench Volcanoes 1. Volcanoes & Plate Tectonics 2. Volcanic Eruptions 3. Extraterrestrial Volcanism Volcanism • Any activity that includes movement of magma toward or onto the surface of the earth – Pockets of magma grow due to melting of nearby rock – Magma pushes upward because it is less dense than solid rock – Overlying rocks break and melt – Magma pockets expand – Magma’s got 2 go somewhere… Volcanoes & Plate Tectonics • What I want to be able to do: – Describe the formation and movement of magma – Define volcanism – List three locations where volcanism occurs Factors that affect eruptions • Magma composition • Magma temperature • Amount of dissolved gas Viscosity • a substance’s resistance to flow – Ex: syrup is more viscous than water – Heat affects viscosity – As lava cools it becomes more viscous and moves much slower • Lava’s viscosity is determined by the silica content Volcanic Material • Dissolved Gasses – Gases trapped in magma cause explosive reactions • Carbon dioxide and water vapor – Reduced pressure at the surface of the mantle allows gases to be released suddenly Volcanic Material • Lava flows – Speed of lava flow depends on slope of land, channel or spread out, type of lava, rate of production – Basaltic lava flows are fast 10300 meters/hour – Rhyolitic lava is often too slow to see Volcanic Material • Pyroclastic materials – Large materials land close building a cone • Lava bombs are extruded in basaltic lava – Smaller material is carried by the wind • Pyroclastic cloud If I Were Magma, Where Would I Come From? • Temperature and pressure conditions need to be just right – The asthenosphere is a zone of the mantle with high temperature and high pressures – Rock in the asthenosphere is usually solid (like plastic goo) because of the high pressure • Magma forms in areas of lower pressure because the rock can move faster and melt Volcanic Cones • Shield Cone – Broad base with gently sloping sides – Result from quiet eruptions (lava flows) – Layers of basaltic lava flow out and harden to build up the cone • Cinder Cone – Very steep slope – Less than a few hundred meters high – Made of solid fragments ejected from volcano – Tephra ejected high into air falls back to Earth in a pile around vent • Composite Cone – Layers from quiet and explosive eruptions – Layers of lava flows and ash If I Were Magma, Where Would I Be? • Most magma forms at plate boundaries – Subduction zones • On the surface – Magma that erupts onto the surface is lava • Vents – Openings through which magma flows onto surface Bellringer • Where are the three major volcano zones located? P. 485 & 486 Major Volcano Zones • Subduction Zones • Mid-Ocean Ridges • Hot Spots Subduction Zones • Where one plate moves under another plate • Oceanic crust under continental crust – Deep trench on ocean floor – Subducting ocean crust forms magma – Mountains along continent edge • Ocean crust under ocean crust – Subducting ocean crust forms magma – Magma rising to the surface forms island arc Mid-Ocean Ridges • Greatest amount of magma comes to surface where plates pull apart • Magma rises to surface through rifts • Lava forms new ocean floor Hot Spots • Areas of volcanism within plates • Hot spots remain stationary, but lithospheric plate moves • Volcano on surface is eventually carried away from the hot spot What To Know About Volcanic Eruptions • What is the relationship between types of lava and the force of eruption? • What are the major types of tephra? • What are the three main types of volcanic cones? • What events might signal that a volcano is going to erupt? Types of Lava • Mafic – Originates from oceanic crust – Dark colored when hardened – Contains lots of magnesium & iron • Felsic – Originates from continental crust – Lighter color when hardened – Contains lots of silica Kinds of Eruptions • Quiet eruption – Mafic lava • Very hot & very thin • Gases do not get trapped – Oceanic volcanoes • Explosive eruption – Felsic lava • Cooler & thicker than mafic lava • Large amounts of trapped gases – Continental volcanoes Why would lava with lots of dissolved gases produce a more explosive eruption? Volcanic Rock Fragments • Felsic lava explosions: – Tephra = rock fragments ejected from volcano – Volcanic ash = tephra particles smaller than 2mm in diameter – Volcanic dust = tephra particles smaller than 0.25mm in diameter – Lapilli = tephra particles smaller than 64mm in diameter – Volcanic bombs = clots of lava thrown from volcano – Volcanic blocks = solid rock blasted from fissure Questions • What is a lava bomb? • What determines the viscosity of a substance? • What is the material ejected from the volcano? Basaltic Lava • • • • Lowest silica content Least viscous Least gas content Least likely to form pyroclastics • Form sheild volcanoes, plateaus, and cinder cones Andesitic Lava • Intermediate silica content • Intermediate viscosity • Intermediate tendency to form pyroclastics • Forms composite cones Rhyolitic lava • • • • • Most silica (70%) Greatest viscosity Most gas content Most likely to form pyroclastic material Forms volcanic domes and Pyroclastic flows Questions???? • What are the 3 types of volcanoes? • What are the three materials produced by a volcano? • Why did the dinosaurs go extinct? Dangers from composite cones • Pyroclastic flows of hot gases, glowing ash, and large rock fragments can rush down slopes at 120 mph • Mud flows called lahars form when large amounts of snow and ice melt and flow down stream channels Volcanic landforms • Caldera – A large depression in the volcano Volcanic Landforms • Necks and Pipes – Pipes connecting magma chamber to the surface Volcanic Landforms • Lava Plateaus – Lava coming through fissures or cracks forms a large flat plateau rather than a cone ??????????????????????????????? • How does magma form? • What are the three zones of Volcanism? volcanism • any activity that includes the movement of magma toward or onto the surface of the earth. magma • liquid rock formed by the melting of solid rock in the asthenosphere • Affected by Temperature Pressure Water Types of Magma • Form three major types of extrusive igneous rock (basalt, andesite, and granite) – Andesitic Magma – silica content between extremes – Basaltic Magma – low silica content – Rhyolitic – high silica content Viscosity – internal resistance to flow • Depends on temperature and composition • High in silica causes it to have a higher viscosity (moves slower) Igneous Melting and crystallization Weathering, erosion, deposition, burial, cementation Metamorphic Sedimentary Heat and temperature, recrystallization Drawing Intrusive Activity • Plutons – intrusive igneous rock bodies – Batholiths – largest, irregularly shaped masses of coarse-grained igneous rocks, many composed primarily of granite, ex: Coast Range Batholith in Columbia – Stocks – irregularly shaped, like batholiths but smaller • Laccoliths – upward bow of rock from heat and pressure of magma body – Mushroom shaped pluton, small, Ex: black hills of South Dakota, the Henry Mts of Utah, Judith mt. of Montana • Sills – magma that intrudes parallel to rock layers • Dikes – pluton that cuts across preexisting rock Types of Volcanoes • Shield – broad gentle sloping sides with nearly circular base - nonexplosive • Cinder cone – small with steep sides formed from materials ejected high into air • Composite – larger than cinder -cone and dangerous layers of volcanic fragments alternate with lava Why Volcanoes Form Locate volcanoes and relate to plate boundaries • Volcanic effects on lithosphere – Convergent, divergent and transform boundaries – Lahar (mud) flows and ash in atmosphere Textbook pages 492-493 (1-21) Earthquakes • Vibration of the earth • Caused by slippage along a break in earths crust Elastic Rebound Theory • Theory used by geologists to explain earthquakes • Rocks on either side of a fault want to slowly move • Stress increases until rocks fracture • Rocks rebound to their original shape (or something close) The results of stress Major cause of folding and faulting is the high pressures and temperatures in the crust. Bellringer • • • • Describe the three types of stress. Tension – pulls apart or lengthens Compression – pushes together or shortens Shear – twists or distorts folding • rock responses to stress by becoming permanently deformed without breaking 3 types of folds: • anticline – upcurved folds in layers (when folds are large they form a ridge) • monocline – gently dipping bends in horizontal rock layers • syncline – downcurved folds in layers ( when folds are large they form a valley) Bellringer • What is the definition of folding and what are the three types of folding? terms • faulting – break in rock where there is movement • fault plane – surface of a fault • hanging wall – rocks above the normal fault plane occur along divergent boundaries • footwall – rocks below the fault plane 3 types of faulting: • normal fault – caused by horizontal tension results in extension of crust Normal fault 3 types of faulting: • reverse fault – fractures form from horizontal compression results in shortening of crust involved – thrust fault – special type of reverse fault where fault plane is at a low angle or nearly horizontal Reverse Reverse fault 3 types of faulting: • strike-slip fault – caused by horizontal sheer results in horizontal movement offsetting features that were originally continuous along the fault. Strike Slip Fault Model of Three Faults Lab • Normal • Thrust • Strike Slip Faults • Fracture in the earths crust where earthquakes occur – Normal Fault • Forces pull apart – Reverse Fault • Forces push together – Strike-Slip or Transform Fault • Forces push opposite directions Earthquake Origin • The focus is where energy is released in lithosphere. • The Epicenter is located on the earth surface directly above the focus Earthquakes • Foreshocks happen before the major earthquake. – Can happen days or even years in advance • Aftershocks happen after the major earthquake. – Can destroy buildings weakened by the original earthquake. Measuring an earthquake • Seismic waves radiate outward in all directions from the focus • 90% of continental earthquakes of a shallow focus – Shallow-focus = within 70km of surface – Intermediate focus = from 70km to 300km – Deep-focus = from 300km to 650km • Why do earthquakes NOT occur deeper than 650km???? Major Earthquake Zones • Most earthquakes occur on or near the edges of plates • Pacific Ring of Fire – West coasts of North & South America – East coast of Asia – Western Pacific islands of Phillipines, Indonesia, New Guinea, & New Zealand • Mid-ocean Ridges • Eurasian-Melanesian Mountain Belt Review 1. What theory do geologists use to explain earthquakes? 2. What is the difference between focus and epicenter? 3. What causes more damage, an earthquake with a shallow focus or an earthquake with a deep focus? 4. Why do earthquakes not generate beyond 650km underground? How do you locate an earthquake? • Epicenter located by analyzing difference in arrival times of P waves and S waves • Need information from at least 3 seismograph stations Lets look at an example Recording Earthquakes • Geologists use seismograph to detect and record seismic waves • Seismograph consists of 3 parts – One records vertical movement of the ground – One records horizontal motion in east-west – One records horizontal motion in north-south Lets look at an example Seismic Waves – Seismic Puzzle • Primary Waves (P waves) – – – – Fastest First to be released causing rock to move back and forth Travel through solids and liquids Compression waves • Secondary Waves (S waves) – – – – Travel through solids Movement of rock particles is at a right angle to wave Cannot be detected on side of earth opposite epicenter Shear waves • Surface Waves (L waves) – Slowest side to side and up and down movement – Most destructive Types of Seismic Waves: • Primary waves – (P waves) move the fastest are the first recorded by seismograph, causes rock particles to move back and forth as it passes • Secondary waves – (S waves) second waves recorded on seismograph movement of rock particles at right angles to the direction of the wave • Surface waves – cause side to side and up and down movement • When P and S waves reach earth’s surface energy is converted to L waves. – Cause the greatest damage Types of Seismic Waves: • Primary waves – (P waves) move the fastest are the first recorded by seismograph, causes rock particles to move back and forth as it passes • Secondary waves – (S waves) second waves recorded on seismograph movement of rock particles at right angles to the direction of the wave • Surface waves – cause side to side and up and down movement • When P and S waves reach earth’s surface energy is converted to L waves. – Cause the greatest damage Bellringer NCFE 2013-2014 #9 • Scientists are studying a graph showing the time differences between the seismic P-waves and the seismic S-waves as they travel through Earth. Which information can they learn from the graph? A. The magnitude of an earthquake B. The duration of an earthquake C. The epicenter of an earthquake D. The intensity of an earthquake • Richter scale – expresses magnitude of quake • Magnitude – measure of energy released by a quake • microquakes – not felt by people magnitude of less than 2.5 • Mercalli scale – expresses the intensity of an quake • intensity - the amount of damage quake causes I. Slinky Lab II. The purpose of this lab is to compare Primary and Secondary waves of an Earthquake. III. If p waves and s waves are simulated, then the _______ wave will move faster. IV. Slinky, stopwatch V. Given on Separate sheet VI. Student Sheet to be completed. Comparing Transverse and Compression Waves • Compressional (Longitudinal) – P waves • Shear (Transverse) – S waves (move through solids but not liquids or gases I. Slinky Lab II. The purpose of this lab is to compare Primary and Secondary waves of an Earthquake. III. If p waves and s waves are simulated, then the _______ wave will move faster. IV. Slinky, stopwatch V. Given on Separate sheet VI. Student Sheet to be completed. Comparing Transverse and Compression Waves • Compressional (Longitudinal) – P waves • Shear (Transverse) – S waves (move through solids but not liquids or gases • http://earthquake.usgs.gov/eqcenter/recente qsww/Quakes/quakes_all.php • http://www.ciese.org/curriculum/musicalplat es3/images/plates.jpg Measuring Earthquakes • Magnitude – Richter Scale (from 0 to 10) – Largest earthquake recorded was a 9.2 <2.0 generally not felt 2.0-2.9 perceptible 3.0-3.9 rarely felt 4.0-4.9 can be felt strongly 5.0-5.9 can be damaging shocks 6.0-6.9 destructive in populous regions 7.0-7.9 Major earthquakes; inflict major damage >8.0 Great earthquakes, destroy communities near epicenter Bellringer NCFE 2013-2014 # 8 Which would produce the most severe earthquake damage along the surface of Earth? A. An earthquake with a deep focus and a magnitude of 2.5 B. An earthquake with a shallow focus and magnitude of 2.5 C. An earthquake with a deep focus and amagnitude of 4.5 D. An earthquake with a shallow focus and a magnitude of 4.5 How do processes change sea level over time –long and short • Infer the effects on landforms such as shorelines and barrier islands San Andreas Fault Activity • San Andreas Fault Video Stress causes Strain • Stress – forces per unit area acting on a material – Compression – Tension – Shear • Strain – deformation of material caused by stress • Elastic or ductile • focus – area along a fault where slippage first occurs and origin of earthquake and waves • epicenter – the point on earth directly above the focus • As distance from epicenter increases the intensity decreases. Three major earthquake zones: • Pacific Ring of Fire (Pacific Oceanic Chain) • Mid-ocean ridges • Euroasian-Melanesian mountain belt • fault zones – groups of interconnected faults at some plate boundaries • seismograph – instrument used to detect and record seismic waves Anatomy of an earthquake p. 494-515 • • • • Epicenter Focal point Relate to plate boundaries Release of energy of various types of quakes relates to magnitude, and P and S waves. Bellringer • Describe the three types of waves produced by an earthquake. P. 498 Ways of predicting quakes: • Locating and mapping faults using instruments to measure changes in the rock movement • seismic gaps – a place where the fault is locked and unable to move • Slight tilting of the ground before a quake and changes in magnetic field • Decrease in speed of local P waves then increase to normal Determining the epicenter • Location of three seismic stations are plotted Earthquake Hazards • • • • structural failure Land and soil failure Fault scarps tsunami Geohazards to protect from: • • • • • • • Meteorological hazards Landslides Earthquakes Tsunamis Sinkholes Groundwater pollution flooding • Tsunami – earthquake with an epicenter on the ocean floor causing a giant ocean wave Major events in the geologic history of NC and the southeastern US Current geologic landforms developed such as Appalachian Mountains, fall zone, shorelines, barrier islands, valleys river basins, etc. using the geologic time scale. Predict the location of volcanoes, earthquakes, and faults based on information contained in a variety of maps • Infer location of volcanoes, earthquakes and faults (strike-slip, reverse and normal) from – Soil – Geologic and topographic map studies – Relate fault location/type to plate boundaries – Make predictions based on data gathered over time in conjunction with various maps Bellringer • What forms at each of the following boundaries? P. 456-458 – Continental- Continental convergent – Continental-oceanic convergent – Oceanic-oceanic convergent – Transform Cookie Mining Activity • Renewable resources – air, sun, soil, water, C, N, and P (recycle naturally) • Nonrenewable resources – fossil fuels, diamonds, gold, silver (long time to make) • Read text p. 663 Bellringer: 1) Name 1 renewable resource and 1 Nonrenewable resource. P. 656 - 657 2) What is the difference between traditional and alternative energy? P. 684 - 697 Warm UP! (answers) 1) Renewable- Plants, Trees, Animals, Water. As long as they are not over used or made unusable to humans. Nonrenewable- Oil, Coal, Gold, Natural Gas. 2) Traditional- The burning of fossil fuels to produce energy. Alternative- The creation of energy in ways that does not burn fossil fuels and avoids negative affects to the planet. Explain consequences of human activities on the lithosphere (such as mining, deforestation, agriculture, overgrazing, urbanization, and land use) past and present p. 659-663 Ways to mitigate detrimental human impacts on the lithosphere and maximize sustainable use of natural resources Effects of human activity on shorelines, especially in development and artificial stabilization efforts Human affects on Mountainsides, especially in development and artificial stabilization efforts Consequences of human activities on the lithosphere Cookie Mining Lab Mining the extraction of valuable minerals or other geological materials from the earth. Deforestation the removal of a forest or stand of trees where the land is converted to a non-forest use. Examples include conversion of forestland to farms, ranches, or urban use. How would the removal of trees and other vegetation impact an environment? A. By increasing oxygen production B. By increasing soil formation C. By increasing transpiration D by increasing erosion Agriculture ( farming) is the cultivation of animals, plants, fungi and other life forms for food, fiber, and other products used to sustain life. Overgrazing when plants are exposed to intensive grazing for long periods of time, or without enough recovery time. -caused by either livestock in poorly managed agricultural applications, or by overpopulations of native or non-native wild animals. Urbanization the physical growth of urban areas as a result of global change. How can urbanization affect a local area? A It can increase the number of invasive species in an area. B It can decrease the risk of water pollution in an area. C It can increase the risk of flooding in an area. D It can decrease the need for natural resources in an area. MAKING NEWS! In the groups I assign, you will research a topic about a human impact on Earths surface. Using the information in your notes and Text Book, your group will create a 2 minute News Story to present to the class in a live studio recording! Information you MUST include in your news story.. A description of the activity you are researching. (Deforestation, Agriculture, overgrazing, urbanization, or mining) Why it occurs. Most importantly: The impact this activity has on the lithosphere. Keep it fun, exciting, and informative! (Why would someone be interested in watching your news report?) Topics and text pages Deforestation - 720, 377,380,437,664 Agriculture – 172-173, 718-719 Overgrazing – 172-173, 718-720 Urbanization – 721-723 Mining- text pages 89-90, 586-587, 663, 716-718 Effects of Mining Landscape changes that result in: Biodiversity loss Rapid erosion Water pollution from toxic metals released Loss of vegetation Effects of Agriculture Accumulation of pesticides, insecticides, and fertilizers Erosion of topsoil Strip soil of vital minerals Effects of deforestation: Soil erosion Soil infertility Loss of biodiversity Increase in surface albedo (sun reflected from Earth’s surface) Increase in CO2 levels Change and reduction in precipitation patterns Increase in global surface temperatures - Activity: simple demonstration of surface erosion Effects of Urbanization High levels of erosion and sedimentation in river Heat islands Pollution of soil by leaking of gas tanks and other chemicals Effects of Overgrazing loss of biodiversity irreversible loss of topsoil desertification increase of turbidity in surface waters increased flooding frequency/intensity. Effects of human activities on Shorelines Mountainsides Deforestation How would you feel if a big corporation cleared the land down the street from you and built a factory? The factory created a great deal of smog and noise 24 hours a day while workers and deliveries added lots of extra traffic noise. And then, as the factory became more successful, the clearing and building expanded, to come closer to you. The community lost it’scommunity garden and the ball field that the neighborhood kids used to play in is now a parking lot…and now they are telling your parents that you will have to move out as they are planning to expand again. What reactions would you have? Which of your constitutional rights (Democratic Principles) would be violated? Where would you turn for help? Pose the above questions to the class. After several minutes of think time, ask the learners to share their reactions. This is what happened to the Native American People of North America and is currently happening to the indigenous people of the Rainforest. Bellringer What is a Heat Island and where does it occur? P.368 Critique conventional and sustainable agriculture and aquaculture practices in terms of their environmental impact. P. 690-703 Economic and environmental impacts Judge potential impact of sustainable techniques on environmental quality Include magnitude, duration and frequency NCES Standard 2.2 Created Fall 2012 Destroying natural areas can reduce the beauty of an area and have a potential economic impact. Rapid development can result in very high levels of erosion and sedimentation in river channels. Pollution of soils is possible by leaking gas tanks and other chemicals. Cutting down all the trees in an area loosens the soil and makes it very easy for extreme erosion to occur. One solution is replanting and a system of harvesting that thins out the area. In Wake County, solid household wastes that cannot be recycled are buried in landfills. If there are hazardous chemicals that leak or heavy metals, it is possible that the soil can be contaminated even though the landfill is lined. Agriculture takes space. Use of chemical pesticides, insecticides and fertilizers can contaminate soil and affect soil fertility. Organic fertilizers are better. Planting the same crop over and over can strip vital minerals out of the soil. Crop rotation can help. Overgrazing is the removal of excessive amounts of plant growth by animals in one area. This accelerates erosion and strips away topsoil, resulting in no plants able to grow. Rotate animals among pastures. Overgrazing by sheep in Patagonia, Chile has lead to major erosion. People require minerals to live, but people also have wants that require minerals. Underground mining requires digging out large areas, increasing the risk for sinkholes and cave ins. Strip mining destroys the environment. Mine operators are required to perform reclamation after finishing with the mining site. This means they must put the land back together and restore it to its original condition. Peat is an accumulation of partially decayed vegetation. Eventually, peat can turn into coal. Peat can be burned for fuel. Advantages low sulphur content minimal mercury content low ash content energy values equivalent to coal less expensive than oil and natural gas and price competitive with other biofuels minor engineering retrofit needed when substituted for, or blended with, coal Since peat forms nearer to the surface, it requires less digging. Oil and Natural Gas are nonrenewable resources that will eventually run out. Drilling can cause the lithosphere to be disturbed. It can cause earthquakes. Soil and groundwater can be contaminated. Fracking: a process where pressurized chemicals and water are injected into the ground enabling access to natural gas. Fracking is a hot political topic because it probably contaminates groundwater. NC is well known for its beaches and Outer Banks. As more and more people retire, there is more development on our coast. Removal of vegetation at the coast can cause serious erosion. The plants help hold the sand in place. Man made erosion control, like sandbags, can make erosion worse downshore. Erosion causes houses to be condemned and potentially fall into the ocean. This house is on our coast and was used in the Nicholas Sparks’ movie “Nights in Rodanthe”. Notice how the water is coming up under the house and it is in danger of falling in the sea. The area around the Cape Hatteras Lighthouse experienced extreme erosion, so it was moved about a ½ mile inland. Why is sea level rising? How do oysters prevent damage from rising sea level? What is the 'Goldilocks' condition for oyster reefs? What do oysters eat? How fast do oysters grow? Should governments pay people to restore oyster reefs? What are 4 ways humans impact beach environments? Explain the negative impact of each. Nourishment and reprofiling – lower number of biodiversity of animals Mechanical beach cleaning – disrupts natural ecological processes and mofifies Blasting away rock to build roads Erosion by building houses and other buildings Remove tops of mountains for mining Logging forests Agriculture In NC North Carolina Farm Facts • Farms in North Carolina - 52,400+ • Land in Farms - 8,600,000 acres + • Average size of Farm - 164 acres + • Farm Real Estate Value per Acre - $4,470 + • Realized Net Farm Income - $3,336,952,000 ++ • Net Income per Farm - $45,532 ++ • Value of Agricultural Exports - $2,743,800,000 +++ • +2010 Estimates, ++2007 Census of Agriculture +++ ERS Field Crops • Tobacco - major cash crop in NC • Cotton - once "king" in North Carolina. Insect problems and the increase of synthetic fibers contributed to the decline of cotton. • Soybeans became an important crop in North Carolina with the increased demand for biofuels • Corn has been produced in most of North Carolina throughout history. • peanut farmers produce some of the best peanuts in the world. Most of North Carolina's peanuts are consumed "out-of-hand," as cocktail peanuts • wheat produced in North Carolina is winter wheat. Unlike most crops, wheat is planted in the fall and harvested in June. This allows farmers to plant another crop on the same acreage after the wheat has been harvested. Livestock • Hogs & pigs have historically been an important part of North Carolina agriculture. North Carolina leads the country in this structural shift towards larger size farms. • Cattle & calves on farms has remained relatively stable throughout time. The northern mountain and northern piedmont counties have traditionally raised the most cattle. Poultry • With the ever increasing demand for chicken, the broiler industry continues to expand. • North Carolina remains a leading state in the production of turkeys. Turkey production continues to be concentrated in the southern piedmont and coastal regions of the State. • The state ranking for table egg production has fluctuated Nursery & Greenhouse • Another part of the diversified agriculture in North Carolina. • There are a large number of acres devoted to Christmas tree production in North Carolina, with the Fraser Fir being the most popular species produced Fruits & Vegetables • North Carolina produces a significant amount of Sweet Potatoes, cucumbers for pickles, lima beans, turnip greens, collard greens, mustard greens, strawberry, bell peppers, blueberries, chile peppers, fresh market cucumbers, snap beans, cabbage, eggplant, watermelons, pecans, peaches, squash, apple, sweet corn, tomatoes, and grapes for millions of people in the United States and numerous other countries. Lincoln county Aquaculture • As North Carolina farmers continue to diversify, aquaculture is an area that has provided opportunities. • North Carolina has become a major producer of trout and catfish. • With increasing recognition that fish is a healthy food for consumers, the increase in demand has allowed aquaculture to be another diverse agriculture crop. Aquaculture • commercial growth growing of fish, mollusk, crustaceans, frogs, and alligators • fish have a higher percentage of edible meat (up to 85%) • up to 6000 pounds fish can be raised on one acre Reasons for aquaculture • many advantages over other agricultural animals • 9lbs. Feed for 1lbs. Of gain for steer • 2lbs. Feed for 1lbs. Of gain a fish • fish are ectothermic (cold-blooded) • this means less energy goes into maintaining a constant body temp Change over the years • Agriculture has changed dramatically, especially since the end of World War II. Food and fiber productivity soared due to new technologies, mechanization, increased chemical use, specialization and government policies that favored maximizing production. These changes allowed fewer farmers with reduced labor demands to produce the majority of the food and fiber in the U.S. Sustainable farming • Sustainable agriculture integrates three main goals--environmental health, economic profitability, and social and economic equity. A variety of philosophies, policies and practices have contributed to these goals. Why Sustainable Agriculture? • Environmental Damage • Animal conditions • Human health Farming and Natural Resources • Water – Water supply and use – Water quality Wildlife Energy Air Soil Farm as an Ecosystem: Energy Flow • Energy flow = pathway of sunlight through a biological system. • In relation to the farm, energy capture is enhanced by maximizing the leaf area available for photosynthesis and by cycling the stored energy through the food chain. • We make money in farming by capturing sunlight – in essence, we are farming the sun (and the soil). Farm as an Ecosystem: Water Cycle • An effective water cycle includes: – no soil erosion – fast water entry into the soil – soil’s ability to store water. • adding to ground cover and soil organic matter enhances the natural water cycle. • Effective water use on the farm results in: – – – – – – low surface runoff low soil surface evaporation low drought incidence low flood incidence high transpiration by plants high seepage of water to underground reservoirs Soil Fertility: Cover Crops Cover Crops – Cover crops improve the soil’s physical properties with carbon and nitrogen cycling. – Reduce erosion and attract beneficial bugs. • Composts – beneficial to build soil organic matter, add nutrients to the soil and retain water. • Crop Rotation – Break weed and pest cycles – Rotate crops to maximize use of nutrient inputs and distribute nutrient demand placed on soil. – Intercropping is the growing of two or more crops in proximity to promote interaction between them. Ecological Pest Management • Intercropping, diversity and cover cropping • Crop rotation • Use of resistant varieties • Biological controls • Organic chemical controls • Physical controls • Integrated Pest Management (IPM) Farm as an Ecosystem: Biodiversity • A farm will be dynamic and healthy if it has a high diversity of plants and animals (aboveground and below). • GREATER DIVERSITY = GREATER STABILITY Social Sustainability • Buying farm supplies locally rather than from out of-state. • Educating your community about sustainable food production. • Direct marketing through CSAs and farmers’ markets builds community and social sustainability. Sustainable Agriculture: • Reduces inputs. • Uses ecological pest and weed management strategies. • Cycles nutrients back into the soil for fertility and health. • Strengthens rural and urban communities. • Produces viable farm income. • Promotes healthy family and social values. • Brings the consumer back into agriculture. Summary – Sustainable agriculture practices • • • • • • • • • • Crop rotation Crop diversity Integrated pest management Attracting beneficial animals Soil fertility Managing grazing Physical removal of weeds Water management Sell locally Use alternative energy Bellringer: NCFE 2014 #3 • Which is a farming technique that could improve the soil and the environment? • A using fueled machines that will turn the soil continuously • B creating undisturbed layers of mulch in the soil • C placing inorganic chemical fertilizers in the soil • D irrigating the soil with salty water I. Sustainability II. Meeting the needs of today without compromising the needs of future generations The Lorax The Lorax Place all of the answers in the back of your notebook. No thneed to write the question! Sustainable Development (SD) Four parts or needs: Human -income, shelter, food, water, safety and health Technology Tools, methods and systems used by humans, energy production, use of natural resources, manufacturing, communication, transportation Economic Specialized in a particular good and/or service Ex: bakers bake bread Environmental Protection, preservation, and conservation of biotic and abiotic resources in the natural world. 1. The Once-ler moved across the land in his wagon. He came upon a new region with an important natural resource. (A natural resource is a plant, animal, or mineral that can be used by people.) What was this natural resource the Once-ler found? 2. Name an important natural resource in your region. 3. The Once-ler used the land's natural resource to start a business which made and sold a product. What was the product? How was it used by buyers? 4. The Lorax appeared at this point and asked the Once-ler some angry questions. What did the Lorax want to know of the Once-ler? How did the Once-ler answer? 5. The Once-ler, like other humans in business, organized a system to manufacture and distribute his product. Listed below are several parts of a manufacturing process. Describe if and how each of the following was used in the story. a. raw materials? __________________________________________ b. product design? ________________________________________ c. labor (workers)? _______________________________________ d. assembly line? _________________________________________ e. energy? ______________________________________________ f. shipping, transportation? __________________________________ g. communication? ________________________________________ h. profits/ losses? ________________________________________ 6. Businessmen, like the Once-ler, sometimes try to make more money by increasing the number of products they can sell. Often new machines and other systems are invented to do this. Other people use machines to work faster, more easily, and more accurately. For example, students, engineers, and others use calculators. Robots are sometimes used to weld sections of cars. Sometimes machines are used to do work humans cannot do. X-ray machines, for example, allow doctors to "see" inside the human body. All these machines are examples of "technology". Often the word "technology" means complicated sets of machines, like those found working together in an automobile plant assembly line. Sometimes "technology" refers to a simple machine like a pencil. Name an example of technology YOU use at home. Name an example of technology YOU use at school. Name an example of technology that YOUR parent might use at work. 7. Now back to the story. What technology did the Once-ler invent to increase the production of thneeds? 8. What are several other examples of technology presented in the story? 9. The use of technology requires the use of natural resources. The use of natural resources often has an effect on the environment. How did the production of thneeds affect a key biotic (i.e., living) natural resource, truffula trees? 10. Threatened and endangered species are those plant and animal populations facing extinction. Often, this is a result of human activity. Can you name several threatened or endangered species and describe why they face this condition? 11. Certain animals depended on truffula trees. Name the animals. Explain why these animals needed truffula trees. 12. Interdependence is an important characteristic of the environment. Living things depend on certain abiotic (non-living) and biotic (living) factors. can you think of a real example in which man's activities have altered the interdependence in natural systems? 12. Interdependence is an important characteristic of the environment. Living things depend on certain abiotic (nonliving) and biotic (living) factors. can you think of a real example in which man's activities have altered the interdependence in natural systems? What are ways humans negatively impact the environment? Deforestation – habitat destruction Pesticide use Introduction of Non Native species Bioaccumulation Acid Rain, Global warming, and smog Releasing excess CO2 by burning fossil fuels Excess Fertilizers released into soil Indirect impact of humans on natural resources 13. Often, technological production creates "byproducts." For example, a byproduct of sawing wood is sawdust. Sometimes the byproducts of technology are unwanted or dangerous (for example, poisonous chemicals) and are pollutants in the environment. Sometimes byproducts are useful. (For example, wood chips can be used to make particle board.) Name two byproducts that resulted from making thneeds. 14. Were the byproducts that resulted from the making of thneeds harmful or helpful to the environment? 15. The fish and swans were affected by the byproducts of making thneeds. Explain how the byproducts and making thneeds affected these animals. Mass Movements, Wind, and Glaciers Factors that affect mass movements: • • • • Materials weight resulting from gravity Materials resistance to sliding or flowing Triggers, such as an earthquake water Types of mass movements: • Creep – very slow • Flows – earth flows (moderately slow) mudflows (swiftly moving • Slides – rapid (landslide) may result in a slump • Avalanche – landslide caused by thick accumulation of snow • Rock falls – rocks fall!!!! Affects on Humans Wind • Erosional agent that modifies landscapes in arid and coastal areas • Transport by: – Saltation – suspension Wind transport causes: • Deflation – lowering (causes desert pavement and deflation blowouts) • Abrasion – erosional activity on rocks – Form ventrifacts Wind deposition • Forms dunes and loess Types of Dunes • Velocity of wind above ground surface determines height of dune • Barchan • Transverse • Parabolic • Longitudinal Loess • Fine grained , light weight particles of silt and clay carried over long distances Glaciers • Large, moving mass of ice • Cover about 10% of earths surface Types of Glaciers • Valley • Continental Glacial Erosion • • • • Great size, weight and density Break rock by plucking Scratches left are called striations and grooves Features made by glaciers include u- shaped valleys, cirques, hornes, and aretes. Glacial Deposition • Left over till forms moraines (terminal, lateral, and medial) • Outwash – sediments deposited by meltwater • Drumlins and eskers • Glacial lakes drumlin esker Explain the probability of and preparation for geohazards such as landslides, avalanches, earthquakes, and volcanoes in a particular area based on available data. • Best locations for various types of development to reduce impacts by geohazards and protect property. Important Terms For Lithosphere Exam • • • • • • • • • • • • • • • • • • Rock cycle Weathering (physical and chemical) Erosion Plates (continental and oceanic) Convergent Divergent Transform fault Intrusive Extrusive Soil Convection currents Fault types (reverse, strike slip, and normal) Epicenter Magma Lava Sedimentary Metamophic focus • • • • • • • • • • • • • • • • Sediment Deposition Lithification Porosity Soil types (temperate, tropical, polar, and desert) Residual soil Transported soil Exfoliation Oxidation Hydrolysis Laccolith Dike Lava flow Sill Volcano types (shield, cinder cone, and composite) Waves (P, S, and surface)
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