1 / 36

Igneous Rocks

Igneous Rocks. Magma – molten rock below the Earth’s surface Granite Diorite Gabbro Peridotite Lava – molten rock extruded on/at the Earth’s surface Rhyolite Andesite Basalt Komatite. Igneous Rocks. Compose or underlie all of the Ocean floors Mid-Ocean ridges Origin of continents

hazel
Download Presentation

Igneous Rocks

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Igneous Rocks • Magma – molten rock below the Earth’s surface • Granite • Diorite • Gabbro • Peridotite • Lava – molten rock extruded on/at the Earth’s surface • Rhyolite • Andesite • Basalt • Komatite

  2. Igneous Rocks • Compose or underlie all of the Ocean floors • Mid-Ocean ridges • Origin of continents • First continents must have appeared as some extrusive/intrusive complex • Make up some of the continents oldest rocks • Zoroaster Granite in the Grand Canyon’s Inner Gorge

  3. Creating Magma • Partial melting • Ice – single mineral melts all at once • Rocks – several minerals that melt at different temps • Heat • Temperature increases with depth • 50-250km are the depths at which rocks begin to melt • Geothermal Gradient • Radioactive decay • Residual heat from formation of planet • Friction at plate boundaries • Pressure • > depth > pressure • Increases melting temperature • Fluids • Mostly water • Decreases melting temperature • Important at plate boundaries

  4. Melting Rocks and Crystallizing Magma • Melting preexisting rocks • Various minerals have different melting temperatures • Composition of melt/liquid changes as new elements are introduced through melting process • Crystallizing magmas • Reverse the melting process • High temp minerals begin to crystallize • Composition of melt changes as elements are extracted through crystallization • Mineral crystals grow as cooling continues and eventually form interlocking crystal structure • Size of crystals is directly related to pace of cooling • Fast cooling small crystals • Slow cooling large crystals

  5. Viscosity of Magmas • Viscosity – resistance to flow • Increases with decreasing temperature • Increases with increasing silica content • Magma rises because • Less dense than surrounding rock • Hotter than surrounding rock • Gas content expands as it rises • Surrounding pressure squeezes it upwards

  6. Bowens Reaction Series • The sequence at which silicate minerals crystallizes as a magma cools • Continuous and discontinuous sides • High temp – Olivine and Ca-plagioclase • Low temp – Quartz and K-feldspar

  7. Bowens Reaction Series

  8. Igneous Textures • Intrusive – Plutonic • Phaneritic – large crystals, easily seen and identified • Cooled slowly underground • Pegmatities – very large crystals, low temp, high water content, often associated with economic deposits • Extrusive – Volcanic • Aphanitic – small crystals, hard to identify without magnification • Cooled quickly, usually above ground • Volcanic glass – obsidian, pumice

  9. Igneous Compositions(Table 4.7) • Felsic – light in color • >65% silica • High viscosity • Al, K, Na • Granites/Rhyolites • Intermediate – usually light in color • 55-65% silica • Medium viscosity • Al, Ca, Na, Fe, Mg • Diorite/Andesite

  10. Igneous Compositions • Mafic – dark in color • 45-55% silica • Low viscosity • Al, Ca, Fe, Mg • Gabbro/Basalt • Ultramafic – dark in color • <40% silica • Very low viscosity • Peridotite/Komatiite

  11. Gabbro/Basalt • Most abundant rock in Earth’s crust • 45-55% silica content • Low viscosity • Pyroxene, Ca-feldspar, olivine (no quartz) • Mafic, dense • Ocean plates, Hawaiian Islands, Northwest U.S. (Columbia Plateau), San Francisco Peaks and surrounding volcanic field (cinder cones – Sunset Crater)

  12. Diorite/Andesite • 55-65% silica content • Sometimes difficult to distinguish between basalt • Amphibole, pyroxene, Ca-to-Na-plagioclase • Second most abundant rock at Earth’s surface • Flows and explosive events • Andes Mtns., Cascades • San Francisco Peaks, Mt. Fuji, Kilimanjaro, Rainier, Vesuvius, Mt St. Helens

  13. Granite/Rhyolite • 65% or more silica content • Intrusive much more common than extrusive • K-feldspars, quartz, Na-plagioclases, sometimes micas • Explosive eruptions • Mt. Elden (intrusive dacite, endogenous/exogenous dome) • Sierra Nevada batholiths • Prescott – Granite Mtn. and Dells • Inner Gorge Grand Canyon – Zoroaster Granite

  14. Plate TectonicsOrigin of Gabbros/Basalts • Mid-ocean ridges • Divergent plate boundaries • Creation of new ocean crust • Gabbros overlain by basalts overlain by sediments (ophiolitic suite) • Ocean island hot-spots • Some continental hot-spots • Varied composition due to assimilation of surrounding country rock

  15. Plate Tectonics Origin of Diorites/Andesites • Subduction zones • Plate collision boundary where one plate overrides another (subduction zone) • Oceanic to cont or oceanic to oceanic • Pacific Ring of Fire • Borders Pacific Ocean • High rate of volcanism and seismic activity • Produced by partial melting of the upper mantle • Inclusion of water and felsic material from the subducting plate • Assimilation of felsic material from surrounding country rock and magma rises

  16. Plate TectonicsOrigin of Granites/Rhyolites • Nearly all occur on continents • Originate from partial melting of crust • Most appear at or near subduction zones • Very viscous • Rise slowly • Generally cool before eruption • Hence larger population of intrusive than extrusive • Produce many economic deposits • Hydrothermal deposits near plutons

  17. Plutons • Tabular - book shaped usually located within zones of weakness • Concordant • Sills – usually in bedding planes etc. • Discordant • Dikes – cut across pre-existing rocks • Massive • Concordant • Laccoliths (mushrooms) • Discordant • batholiths

  18. Shield VolcanoMauna Loa

  19. Basalt FlowMafic/low silica/low viscosity

  20. Lava FountainMafic/low silica/low viscosity

  21. Aa LavaMafic/low silica/low viscosity

  22. Pahoehoe LavaMafic/low silica/low viscosity

  23. Spatter coneMafic/low silica/low viscosity

  24. Pillow LavaMafic/low silica/low viscosity

  25. Andesite Mt. St. HelensIntermediate/mod silica/mod viscosity

  26. Mt. St. Helens BulgeIntermediate/mod silica/mod viscosity

  27. Mt. St. Helens PyroclasticInter/mod silica/mod viscosity

  28. Mt. St. Helens afterInter/mod silica/mod viscosity

  29. Mt. St. Helens before 1980 eruption

  30. Mt. St. Helens lahar eruption and deposit

  31. Mt. St. Helens domeFelsic/hi silica/hi viscosity

  32. Alaskan DomeFelsic/hi silica/hi viscosity

  33. Mt. St. Helens pumice flowFelsic/hi silica/hi viscosity

  34. TephraFelsic/hi silica/hi viscosity

  35. Volcanic necks

  36. Volcanic Neck – Shiprock, N. Mexico

More Related