1 / 19

Important Types of Ore Deposits

Important Types of Ore Deposits. Affect of Elements on Mineral Color. The major factors responsible for the production of color in minerals fall into five categories: 1) The presence of an element essential to the mineral composition 2) The presence of a minor chemical impurity

stacey
Download Presentation

Important Types of Ore Deposits

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. Important Types of Ore Deposits

  2. Affect of Elements on Mineral Color • The major factors responsible for the production of color in minerals fall into five categories: 1) The presence of an element essential to the mineral composition 2) The presence of a minor chemical impurity 3) Physical defects in the crystal structure 4) The mechanical mixture of very fine impurities 5) The presence of finely-spaced structures in the mineral

  3. Chromium, Cr, produces the color orange-red color of crocoite, (lead chromate).PbCrO4 • Copper, Cu, produces the azure blue color of azurite, (copper carbonate hydroxide).Cu3(CO3)2(OH)2 • Iron, Fe, produces the red color of limonite, (hydrated iron oxide hydroxide). Fe2O3.H2O • Manganese, Mn, produces the pink color of rhodochrosite, (manganese carbonate).MnCO3 • Vanadium, V, produces the red-orange color of vanadinite, (lead vanadate chloride)Pb5(VO4)3Cl

  4. Beryl Be3Al2(SiO3)6 • Beryl containing iron (Fe): • Aquamarine = Fe++, beryl is blue • Heliodor = Fe+++, yellow • Green beryl :  due to mixtures of Fe2+ and Fe3+ • Beryl containing Manganese(Mn): • Morganite : Mn++ is pink • Red beryl : Mn+++ is red • Beryl containing Chromium(Cr): • Emerald = emerald green : Cr+++ • Oxidation state (e.g., Fe2+ vs. Fe3+) also affects the color!

  5. Skarn Deposits • Skarn deposits are formed by high temperature contact metamorphic processes where a silicic magma (granite) intrudes carbonate rocks • Common minerals include magnetite, molybdenite, sphalerite, galena, scheelite, hematite, garnet, epidote • Important source of tungsten, iron, molybdenum, zinc, lead Evans 1997

  6. Papoose Flat Skarn, E. CA Limestone near pluton Limestone away from pluton Skarn

  7. Volcanogenic Massive Sulfide Deposits (VMS) • Volcanogenic massive sulfide ore deposits (VMS) are a type of Cu-Zn ore deposit associated with hydrothermal events. They are predominantly stratiform accumulations of sulfide minerals that precipitate from hydrothermal fluids in a wide range of ancient and modern geological settings (especially the seafloor but also land-based volcanics). • VMS represent a significant source of the world's Cu, Zn, Pb, Au, and Ag ores, with Co, Sn, Ba, S, Se, Mn, Cd, In, Bi, Te, Ga and Ge as co- or by-products. • VMS deposits consists of over 90% iron sulfide! • Pyrite, Chalcopyrite, Galena, Sphalerite, Barite Simplified MVS Deposit- Bent Hill Or hot springs

  8. VMS • Most VMS deposits show metal zonation, caused by the changing physical and chemical environments of the circulating hydrothermal fluid. Ideally, this forms a core of massive pyrite and chalcopyrite around the throat of the vent system, with a halo of chalcopyrite-sphalerite-pyrite grading into a distal sphalerite-galena and galena-manganese and finally a chert-managanese-hematite facies.

  9. VMS Today • VMS deposits are forming today on the seafloor around undersea volcanoes along many mid ocean ridges, and within back-arc basins and forearc rifts (regions of extension and crustal thinning). Black Smoker White Island, New Zealand

  10. Mississippi Valley Type Deposits (MVT) • MVTs are hydrothermal lead-zinc ore deposits that are characterized by • (1) low-temperature formation (100°-150°C) • (2) epigenetic (forming after) emplacement within restricted dolostone or limestone strata of sedimentary basins (i.e., stratigraphically controlled) • (3) precipitation from highly saline brines • (4) the presence of barite and/or fluorite mineralization • MVT deposits tend to occur in clusters at the margins of sedimentary basins, and they are intimately associated with the evolution of these basins. • They are also typically found far from, and lack a genetic relationship to, igneous activity or igneous rocks.

  11. MVTs • Although they are found around the globe, the MVTs within the Mississippi River drainage basin are the largest and were the first to be studied in detail. • The most abundant minerals in MVTs are sphalerite and galena, barite, fluorite, calcite, dolomite, quartz and pyrite Galena Calcite on fluorite Sphalerite

  12. Porphyry Copper Deposit reynolds.asu.edu/sierra_cobre/p_formation.gif

  13. Porphyry Copper Deposits • Characteristic alteration and mineralization zones around the porphyry • Groundwater is very important for concentrating copper minerals • Pyrite, chalcopyrite, molybdenite, bornite, native copper Bingham Copper Mine, Utah

  14. Borax Deposits, US Borax Mine, Boron, CA • 19 Ma, active lava flows spread across the Mojave Desert. Over thousands of years, water collected in the basin, forming a lake. Clay from the surrounding rock formed an impermeable layer at the bottom. • Hot springs rich in boron flowed into the lake, quickly cooling to form borax crystals. Finally, another layer of clay washed in, sandwiching the borax deposit in between (stratiform deposit). Then the lake dried up. • Boron and Searles Lake (in E. CA) produce 95% of the world’s borax!

  15. Pegmatites • Pegmatites are coarse-grained igneous rocks of granitic composition, typically forming dikes. • Most common minerals are quartz, feldspars, and micas. • The crystals formed in pegmatite dikes are large because the molten material is accompanied by an unusually large amount of water-rich gas. Without the gas, granite will form. • Gem pockets form where the gas is trapped to form a large bubble. This allows crystals free growth. Rare elements are concentrated in the gas and account for the unusual compositions and colors. • Lepidolite associated with pegmatites is the main source of the rare metal lithium

  16. Bauxite Deposits • Bauxite is an aluminum ore and is not actually a mineral. It consists largely of gibbsite Al(OH)3, diaspore AlOOH, together with hematite, the clay mineral kaolinite and small amounts of anatase TiO2. • Bauxite occurs in many countries of the tropical belt. Largest producers are Australia, Jamaica and Guinea. • It is formed by lateritization (intense chemical weathering in hot, wet, tropical areas) of various silicate rocks such as granite, gneiss, basalt, and shale.

  17. Epithermal Gold Deposits • Epithermal gold deposits (like CA’s Mother Lode) form when hydrothermal fluids infiltrate cracks and faults in the rock. • The gold is commonly associated with quartz veins • Rock permeability is highest immediately following earthquakes. This is when most epithermal mineralization occurs. • Tectonic setting is very important for this type of gold deposit

  18. Summary • Ore deposits typically require: • Heat • Permeability (faults/fractures) • Mineralizing fluid • Specific rock types • Specific tectonic conditions

  19. Created by Nicolas Barth2007Geology 114AUniversity of California, Santa BarbaraSome images herein borrowed from websites have not been credited

More Related