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Chapter 7 Fires Within: Igneous Activity

Chapter 7 Fires Within: Igneous Activity. The Nature of Volcanic Eruptions. Characteristics of a magma determine the “violence” or explosiveness of an eruption Composition Temperature Dissolved gases The above three factors actually control the viscosity of a magma.

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Chapter 7 Fires Within: Igneous Activity

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  1. Chapter 7 Fires Within: Igneous Activity

  2. The Nature of Volcanic Eruptions • Characteristics of a magma determine the “violence” or explosiveness of an eruption • Composition • Temperature • Dissolved gases • The above three factors actually control the viscosity of a magma

  3. The Nature of Volcanic Eruptions • Viscosity is a measure of a material’s resistance to flow • Factors affecting viscosity • Temperature—Hotter magmas are less viscous • Composition—Silica (SiO2) content • Higher silica content = higher viscosity • Lower silica content = lower viscosity

  4. The Nature of Volcanic Eruptions • Dissolved gases • Gases expand within a magma as it nears Earth’s surface due to decreasing pressure • The violence of an eruption is related to how easily gases escape • In summary • Basaltic lavas = mild eruptions • Rhyolitic or andesitic lavas = explosive eruptions

  5. Materials Extruded from a Volcano • Lava flows • Basaltic lavas exhibit fluidbehavior • Types of basaltic flows • Pahoehoe lava (resembles a twisted or ropey texture) • Aa lava (rough, jagged blocky texture) • Dissolved gases • 1%–6% by weight • Mainly H2O and CO2

  6. Aa Lava Flow

  7. Aa Lava

  8. Pahoehoe Lava

  9. Pahoehoe Lava - Hawaii

  10. Materials Extruded from a Volcano • Pyroclastic materials—“Fire fragments” • Types of pyroclastic debris • Ash and dust— Fine, glassy fragments • Pumice—Porous rock from “frothy” lava • Cinders — Pea-sized material • Lapilli — Walnut-sized material • Particles larger than lapilli • Blocks—Hardened or cooled lava • Bombs—Ejected as hot lava

  11. Volcanic Ash

  12. A Volcanic Bomb

  13. Volcanic Structures • General features • Opening at the summit of a volcano • Crater—Summit depression <1 km diameter • Caldera—Summit depression >1 km diameter produced by collapse following a massive eruption • Vent—Surface opening connected to the magma chamber • Fumarole—Emit only gases and smoke

  14. Kilauea – crater and caldera

  15. Volcanic Structures • Types of volcanoes • Shield volcano • Broad, slightly domed shape • Generally cover large areas • Produced by mild eruptions of large volumes of basaltic lava • Example = Mauna Loa on Hawaii

  16. Mauna Loa, a Shield Volcano on Hawaii Figure 7.9

  17. Volcanic Structures • Cinder cone • Built from ejected lava (mainly cinder-sized) fragments • Steep slope angle • Small size • Frequently occur in groups

  18. Cinder cone

  19. Cinder cone - Paricutin

  20. Cinder Cone Volcano Figure 7.12

  21. Volcanic Structures • Composite cone (stratovolcano) • Most are located adjacent to the Pacific Ocean (e.g., Fujiyama, Mount St. Helens) • Large, classic-shaped volcano (1000s of ft. high and several miles wide at base) • Composed of interbedded lava flows and pyroclastic debris • Most violent type of activity (e.g., Mt. Vesuvius)

  22. Mount St. Helens—Prior to the 1980 Eruption

  23. Mount St. Helens after the 1980 Eruption

  24. Mount St. Helens - 2006

  25. Profiles of Volcanic Landforms Figure 7.10

  26. Volcanic Structures • Nuée ardente • Nuée ardente—A deadly pyroclastic flow • Fiery pyroclastic flow made of hot gases infused with ash and other debris • Also known as glowing avalanches • Move down the slopes of a volcano at speeds up to 200 km per hour

  27. A Nueé Ardente on Mount St. Helens Figure 7.15

  28. Nueé Ardente – Mount Pelée

  29. Volcanic Structures • Lahar—Volcanic mudflow • Mixture of volcanic debris and water • Move down stream valleys and volcanic slopes, often with destructive results

  30. Lahar—Volcanic mudflow

  31. Other Volcanic Landforms • Caldera • Steep-walled depressions at the summit • Generally >1 km in diameter • Produced by collapse • Pyroclastic flow • Felsic and intermediate magmas • Consists of ash, pumice, and other debris • Example = Yellowstone Plateau

  32. Formation of Crater Lake, Oregon Figure 7.18

  33. Yellowstone Plateau

  34. Other Volcanic Landforms • Fissure eruptionsandlava plateaus • Fluid basaltic lava extruded from crustal fractures called fissures • Example = Columbia River Plateau

  35. Fissure eruptions

  36. Lava plateaus

  37. Columbia River plateau

  38. Other Volcanic Landforms • Volcanic pipes and necks • Pipes—Short conduits that connect a magma chamber to the surface • Volcanic necks (e.g., Shiprock, New Mexico)—Resistant vents left standing after erosion has removed the volcanic cone

  39. Volcanic necks

  40. Devils Tower - Wyoming

  41. Intrusive Igneous Activity • Most magma is emplaced at depth in the Earth • Once cooled and solidified, is called a pluton • Nature of plutons • Shape—Tabular (sheetlike) vs. massive • Orientation with respect to the host (surrounding) rock • Concordant vs. discordant

  42. Intrusive Igneous Activity • Types of intrusive igneous features • Dike—A tabular, discordant pluton • Sill—A tabular, concordant pluton (e.g., Palisades Sill in New York) • Laccolith • Similar to a sill • Lens or mushroom-shaped mass • Arches overlying strata upward

  43. Igneous Structures Figure 7.22 B

  44. A Sill in the Salt River Canyon, Arizona Figure 7.23

  45. Intrusive Igneous Activity • Intrusive igneous features continued • Batholith • Largest intrusive body • Surface exposure >100+ km2 (smaller bodies are termed stocks) • Frequently form the cores of mountains

  46. Sierra Nevada Batholith

  47. Half Dome – Yosemite N.P.

  48. Columnar Jointing

  49. Columnar Jointing LED ZEPPELIN – Houses of the Holy

  50. Plate Tectonics and Igneous Activity • Global distribution of igneous activity is not random • Most volcanoes are located within or near ocean basins • Basaltic rocks = oceanic and continental settings • Granitic rocks = continental settings

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