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Living Physical Geography, 1 st Edition

Living Physical Geography, 1 st Edition. c . 2014 W.H. Freeman & Co. By Bruce Gervais. Chapter 14. Geohazards: Volcanoes and Earthquakes. Geohazard. A hazard posed to people by the physical Earth. Examples of Geohazards. Volcanic eruptions Earthquakes Tsunamis Floods Landslides

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Living Physical Geography, 1 st Edition

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  1. Living Physical Geography, 1st Edition c. 2014 W.H. Freeman &Co.By Bruce Gervais

  2. Chapter 14 Geohazards: Volcanoes and Earthquakes

  3. Geohazard A hazard posed to people by the physical Earth

  4. Examples of Geohazards • Volcanic eruptions • Earthquakes • Tsunamis • Floods • Landslides • Rockfalls

  5. Tsunami A large ocean wave triggered by an earthquake or other natural disturbance

  6. About Volcanoes • Active Volcanoes: Those that have erupted in the last 10,000 years and could erupt again • Dormant Volcanoes: Those that have not erupted for 10,000 years or more, but could awaken again • Extinct Volcanoes: Those that have not erupted for tens of thousands of years and can never erupt again

  7. Three Types of Volcanoes • Stratovolcanoes (composite volcanoes) • Shield volcanoes • Cinder Cones

  8. Stratovolcano (composite volcano): A large, potentially explosive cone-shaped volcano composed of alternating layers of lava and pyroclast Pyroclasts, or pyroclastic materials, encompass any fragmented solid material that is ejected from a volcano.

  9. Shield Volcano • Abroad, domed volcano formed from many layers of fluid basaltic lava Shield volcanoes are much larger than stratovolcanoes, and can be difficult to identify as volcanoes from the ground.

  10. Shield Volcano Structure

  11. Cinder Cone • Small, cone-shaped volcanoes consisting of pyroclasts that settle at the angle of repose The angle of repose is the steepest angle at which loose sediments can settle.

  12. Cinder Cone Structure

  13. Three Types of Volcanic Products • Lavas • Pyroclasts • Gases

  14. Lavas Mafic Intermediate Felsic • Temperature of about 1,000°C to 1,200°C (1,800°F to 2,200°F) • Silica content of 50% or less • Low viscosity and flows easily • Temperature of about 800°C to 1,000°C (1,500°F to 1,800°F) • Silica content between 50% and 70% • Medium viscosity • Temperature of about 650°C to 800°C (1,200°F to 1,500°F) • Silica content of 70% or more • High viscosity restricts its ability to flow

  15. Lava Viscosities

  16. Mafic Lava Types • When mafic lava solidifies into smooth, billowy lobes over the surface, it is called Pāhoehoe. • When it takes on a blocky, rough surface, it is called ʻAʻā.

  17. Lava Lakes

  18. Types of Pyroclasts • Volcanic ash: Fine volcanic powder consisting of pulverized rock particles and solidified droplets of lava • Lapilli: Marble-to golf ball-sized cooled fragments of lava

  19. Types of Pyroclasts • Pumice: A lightweight, porous rock with at least 50% air content

  20. Types of Pyroclasts • Volcanic bombs: A streamlined fragment of lava ejected from a volcano that cooled and hardened as it moved through the air • Volcanic blocks: A fragment of rock from the volcano’s cone that is ejected during an explosive eruption

  21. Volcanic Gases • Gas is not a pyroclastic material, but gas emissions produce pyroclasts. • As gas forcefully exits a volcano, it blasts lava and rock debris into the air, generating pyroclasts.

  22. Volcanic Landforms • Volcanic landforms are typically very conspicuous on Earth’s surface. • Some common volcanic landforms are volcanic mountains, columnar jointing, large igneous provinces, and calderas.

  23. Columnar Jointing A geometric pattern of angular columns that forms from joints in basaltic lava during cooling

  24. Large Igneous Province An accumulation of flood basalts that covers an extensive geographic area

  25. Caldera A large depression that forms when a volcano’s magma chamber empties and collapses after the volcano erupts

  26. Caldera Formation

  27. Calderas

  28. Two Kinds of Eruptions: • Effusive: Anonexplosive eruption that produces mostly lava, (e.g., shield volcanoes) • Explosive: An eruption that sends rock, ash, and volcanic gases high into the troposphere, or even into the stratosphere, (e.g., many stratovolcanoes)

  29. Ranking Volcano Strength: The Volcanic Explosivity Index (VEI) • Ranks volcanic eruption magnitude based on the amount of material a volcano ejects during an eruption

  30. Volcanic Intensity Comparison

  31. Volcanoes' Two Greatest Threats • Lahars • Pyroclastic Flows

  32. Lahar A thick slurry of mud, ash, water, and other debris that flows rapidly down a snowcapped stratovolcano when it erupts

  33. Pyroclastic Flow • Arapidly moving avalanche of searing hot gas and ash

  34. The Destruction of Pompeii

  35. Can Scientists Predict Volcanic Eruptions? • Scientists can sometimes predict an eruption within weeks or months if a volcano gives warning signs.

  36. The Pacific Ring of Fire • More than 60% of the Pacific Ocean’s margins are subduction zones with active and dangerous stratovolcanoes. • Although shield volcanoes are found in the Pacific Ring of Fire, explosive stratovolcanoes are the most common type of volcano there.

  37. Tectonic Hazards: Faults and Earthquakes • Although usually less noticeable than volcanic hazards, earthquakes are as dangerous as volcanoes, or even more so.

  38. Three Types of Faults Normal Fault Reverse Fault Strike-Slip Fault • Occurs where one block moves horizontally in relation to another block as a result of shearing (lateral) force • A result of tensional force (extension) as two pieces of Earth’s crust, called fault blocks, are pulled apart • Results from compressional force, which pushes one block upward in relation to another block

  39. Three Types of Faults

  40. Fault Indicators Reverse and normal faults create a fault scarp, or cliff face, that results from the vertical movement of the fault blocks.

  41. Where strike-slip faults cross linear features, those features may be offset by fault movement, (left-lateral and right-lateral).

  42. How Do Earthquakes Occur? • Earthquakes occur when geologic stress exceeds friction, and the crust breaks (either along a preexisting fault or along a new fault), and the blocks move. • As each block moves, the built-up stress energy is released and travels through the crust as seismic waves, resulting in an earthquake.

  43. Earthquake Terminology • Focus: The location of initial movement along a fault during an earthquake • Epicenter: The location on the ground’s surface immediately above the focus of an earthquake, where earthquake intensity is usually greatest • Foreshock: A small earthquake that sometimes precedes a larger earthquake • Aftershock: A small earthquake that follows the main earthquake

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