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Earth Resources

Earth Resources. Geology Today Chapter 16 Barbara W. Murck and Brian J. Skinner. Petroleum, solar energy, and biomass - California. N. Lindsley-Griffin, 1999. Mineral Deposits.

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Earth Resources

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  1. Earth Resources Geology Today Chapter 16 Barbara W. Murck and Brian J. Skinner Petroleum, solar energy, and biomass - California N. Lindsley-Griffin, 1999

  2. Mineral Deposits Reserve - known resource that can be extracted profitably at current market conditions and levels of technology Source: U.S. Geological Survey

  3. Mineral Deposits Mineral deposit - a naturally occurring accumulation of mineral material of potential economic value Ore - the naturally occurring material from which a mineral can be profitably extracted Banded Iron Deposit, Lake Superior N. Lindsley-Griffin, Dolgoff, 1998

  4. Mineral Deposits The plate tectonic setting controls which mineral deposits form Fig. 16.21, p. 493 j N. Lindsley-Griffin, 1999

  5. Mineral Deposits Mineral deposits form by natural Earth processes: At depth, from internal heat and pressure Near the surface, from rock interactions with atmosphere and hydrosphere N. Lindsley-Griffin, 1998

  6. Mineral Deposits Deepmineralizing processes at:Divergent marginsConvergent marginsHot spots Mt. Hood, Oregon Types of deposits: Magmatic Hydrothermal Metamorphic Migmatite, Wyoming N. Lindsley-Griffin, 1999

  7. Mineral Deposits Layered gabbro, Smartville ophiolite, CA MagmaticDepositsForm as molten magmas crystallize Metallic minerals settle to form layers in the magma chamber Chromium Platinum N. Lindsley-Griffin, 1999

  8. Mineral Deposits Model for magmatic deposit formation Fig. 16.24, p.497 Chromite and plagioclase layers, Bushveld complex,South Africa N. Lindsley-Griffin, 1999

  9. Mineral Deposits Hot water and sulfide particles issuing from a black smoker, East Pacific Rise Hydrothermal Deposits Sulfide minerals deposited here Hot water and gases circulate through fractures in crust Metal ions leached from rock at depth are concentrated and redeposited Gold, zinc, lead, copper Woods Hole Oceanographic Institution N. Lindsley-Griffin, 1998

  10. Mineral Deposits Hydrothermal deposits in ophiolites (on-land fragments of ocean lithosphere) Veins are deposited along fractures in basalts of oceanic crust - Divergent margins, oceanic rift valleys Ores are transported by subduction and plate movement, emplaced on land by terrane accretion in ophiolites - Convergent margins, active continental margins Houghton Mifflin,Dolgoff, 1998; N. Lindsley-Griffin, 1999

  11. Mineral Deposits Hydrothermal deposits associated with convergent margins form beneath stratovolcanoes. Hydrothermal solutions deposit copper-iron sulfides in porphyritic andesites - porphyry copper deposits Metallogenic province of rich porphyry-copper deposits along the western edge of the Americas Skinner et al., 1999; N. Lindsley-Griffin, 1999

  12. Mineral Deposits Hydrothermal veins may form at depth beneath any volcano Geologist inspects a hydrothermal gold vein being mined at Cripple Creek, Colorado (Fig. 16.22, p. 496) N. Lindsley-Griffin, 1999

  13. Mineral Deposits Hydrothermal ore deposits are forming today in the Imperial Valley of California - a graben formed by rifting along the northern end of the East Pacific Rise which runs up Gulf of CA.Metallic ions are leached from the sediments under the graben by hot fluids resulting from volcanism.Hot brines deposit siliceous scale containing 20% copper and 8% silver on the insides of pipes in drilled wells. Fig. B16.1, p. 494 N. Lindsley-Griffin, 1999

  14. Mineral Deposits Hydrothermal deposits forming today in the Red Sea: Hot, dense brines rise up along normal faults that bound the graben. Heated by deep magmas along the oceanic rift, they precipitate chalcopyrite, galena, and sphalerite as they cool. Fig. B16.2, p. 495 N. Lindsley-Griffin, 1999

  15. Mineral Deposits Hydrothermal deposits forming today in the Red Sea: Brines remain pooled in the deep graben because they are denser than sea water. This hydrothermal deposit is called a stratabound deposit, because the minerals are precipitated as layers interbedded with sediments. Fig. B16.2, p. 495 N. Lindsley-Griffin, 1999

  16. Mineral Deposits Stratabound ore of lead and zinc; Kimberley, British Columbia. Layers of pyrite (yellow), sphalerite (brown), and galena (gray) are parallel to the layering of the sedimentary host rock. Skinner et al., 1999; N. Lindsley-Griffin, 1999

  17. Mineral Deposits Metamorphic deposits form by the heat, pressure, liquids associated with metamorphism Iron ores, marble, serpentine N. Lindsley-Griffin, 1998

  18. Mineral Deposits Metamorphic deposits form by two main processes: 1) recrystallization during regional metamorphism along convergent margins 2) contact metamorphism by hot solutions (hydrothermal solutions) near magma Houghton-Mifflin, Dolgoff, 1998; N. Lindsley-Griffin, 1999

  19. Mineral Deposits Scheelite (CaWO4) Metamorphism - ores of tungsten, zinc and iron Pyrite (FeS) Ore, Tem-Piute Mine, NV (Fig. 16.23, p. 496) Calcite (CaCO3) Fluorite (CaF) N. Lindsley-Griffin, 1999

  20. Mineral Deposits Shallow mineral deposits form by: Surface water Mechanical concentration Evaporation Groundwater Leaching Secondary enrichment Biochemical reactionsin seawater Types of deposits: Sedimentary Placer Residual N. Lindsley-Griffin, 1998

  21. Mineral Deposits Sedimentary deposits form by evaporation and precipitation Anhydrite, gypsum, halite Evaporite Deposits at Bonneville Salt Flats, Utah N. Lindsley-Griffin, 1998

  22. Mineral Deposits Sedimentary deposits form by biochemical reactions in seawater Banded iron formations were precipitated by biochemical reactions in a low-oxygen atmosphere during the Precambrian Banded Iron Deposit, Lake Superior N. Lindsley-Griffin, 1998

  23. Concentric rings enriched in: Copper, Cobalt, Nickel, Manganese Manganese Nodules form by direct precipitation from seawater Metallic ions from mid-ocean ridge hydrothermal vents Cold water lowers solubility Found in thin marine oozes (young crust or slow sedimentation) Best commercial potential: central Pacific Ocean N. Lindsley-Griffin, 1998; Dolgoff, 1998

  24. Mineral Deposits Mechanical Concentration Olivine beach placers, South Point, Hawaii Placer deposits: Heavy grains sorted by currents Deposited in rivers or beaches Previously weathered from bedrock source Gold, platinum, diamonds, chromite, Zirconium and Titanium minerals N. Lindsley-Griffin, 1998

  25. Mineral Deposits Placers are deposited: Behind rock bars In rock holes Below waterfalls In point bars inside meander loops Downstream from a tributary Along beaches and behind undulations on the ocean floor. N. Lindsley-Griffin, 1999

  26. Mineral Deposits Residual mineral deposits form by chemical weathering Soluble minerals are leached- dissolved by rain water and carried downward by infiltration, leaving behind less soluble minerals. Laterites are mined for iron and sometimes nickel. Iron ore, Australia N. Lindsley-Griffin, 1999

  27. Mineral Deposits Residual mineral deposits Bauxiteis the main source of aluminum ore - found in laterites formed in tropical climates. Fig. 16.26, p. 499 Bauxite (aluminum ore) Weipa, Australia N. Lindsley-Griffin, 1999

  28. Secondary Enrichment - metals leached from the surface are precipitated below the water table Upper zone: insoluble iron oxides left behind Leaching Precipitation Phelps-Dodge-Morenci open pit copper mine, Clifton, Arizona Enriched zone: soluble metal sulfides of Zn, Pb, Cu, Au, Ag, Hg, Fe N. Lindsley-Griffin; Dolgoff, 1998

  29. Mining Mining can harm the environment if not done properly - that’s one reason why recycling is beneficial Sound mining practices include: Reclamation of mined areas Proper disposal of tailings and waste water Subsurface mine shaft Surface mine Spoil Banks Acid spill in stream Houghton Mifflin, Dolgoff, 1998; N. Lindsley-Griffin, 1999

  30. Mineral Deposits REVIEW: plate tectonic setting controls which mineral deposits form Fig. 16.21, p. 493 j N. Lindsley-Griffin, 1999

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