Galena Explained

Galena
Category:Sulfide mineral
Formula:PbS
Imasymbol:Gn[1]
Strunz:2.CD.10
Dana:2.8.1.1
System:Cubic
Class:Hexoctahedral (mm)
H–M symbol:
Symmetry:Fmm
Unit Cell:a = 5.936 Å; Z = 4
Color:Lead gray and silvery
Habit:Cubes and octahedra, blocky, tabular and sometimes skeletal crystals
Twinning:Contact, penetration and lamellar
Cleavage:Cubic perfect on, parting on
Fracture:Subconchoidal
Tenacity:Brittle
Mohs:2.5–2.75
Luster:Metallic on cleavage planes
Opticalprop:Isotropic and opaque
Streak:Lead gray
Gravity:7.2–7.6
Fusibility:2
Diaphaneity:Opaque
Other:Natural semiconductor
References:[2] [3] [4]

Galena, also called lead glance, is the natural mineral form of lead(II) sulfide (PbS). It is the most important ore of lead and an important source of silver.[5]

Galena is one of the most abundant and widely distributed sulfide minerals. It crystallizes in the cubic crystal system often showing octahedral forms. It is often associated with the minerals sphalerite, calcite and fluorite.

Occurrence

Galena is the main ore of lead, used since ancient times,[6] since lead can be smelted from galena in an ordinary wood fire.[7] Galena typically is found in hydrothermal veins in association with sphalerite, marcasite, chalcopyrite, cerussite, anglesite, dolomite, calcite, quartz, barite, and fluorite. It is also found in association with sphalerite in low-temperature lead-zinc deposits within limestone beds. Minor amounts are found in contact metamorphic zones, in pegmatites, and disseminated in sedimentary rock.[8]

In some deposits, the galena contains up to 0.5% silver, a byproduct that far surpasses the main lead ore in revenue.[9] In these deposits significant amounts of silver occur as included silver sulfide mineral phases or as limited silver in solid solution within the galena structure. These argentiferous galenas have long been an important ore of silver.[10] Silver-bearing galena is almost entirely of hydrothermal origin; galena in lead-zinc deposits contains little silver.[8]

Galena deposits are found worldwide in various environments.[4] Noted deposits include those at Freiberg in Saxony;[2] Cornwall, the Mendips in Somerset, Derbyshire, and Cumberland in England; the Linares mines in Spain were worked from before the Roman times until the end of the 20th century;[11] the Madan and Rhodope Mountains in Bulgaria; the Sullivan Mine of British Columbia; Broken Hill and Mount Isa in Australia; and the ancient mines of Sardinia.

In the United States, it occurs most notably as lead-zinc ore in the Mississippi Valley type deposits of the Lead Belt in southeastern Missouri, which is the largest known deposit,[2] and in the Driftless Area of Illinois, Iowa and Wisconsin, providing the origin of the name of Galena, Illinois, a historical settlement known for the material. Galena also was a major mineral of the zinc-lead mines of the tri-state district around Joplin in southwestern Missouri and the adjoining areas of Kansas and Oklahoma.[2] Galena is also an important ore mineral in the silver mining regions of Colorado, Idaho, Utah and Montana. Of the latter, the Coeur d'Alene district of northern Idaho was most prominent.[2]

Australia is the world's leading producer of lead as of 2021, most of which is extracted as galena. Argentiferous galena was accidentally discovered at Glen Osmond in 1841, and additional deposits were discovered near Broken Hill in 1876 and at Mount Isa in 1923.[12] Most galena in Australia is found in hydrothermal deposits emplaced around 1680 million years ago, which have since been heavily metamorphosed.[13]

The largest documented crystal of galena is composite cubo-octahedra from the Great Laxey Mine, Isle of Man, measuring 25×.[14]

Importance

Galena is the official state mineral of the U.S. states of Kansas, Missouri,[15] and Wisconsin;[16] the former mining communities of Galena, Kansas,[17] [18] Galena, Illinois,[19] Galena, South Dakota and Galena, Alaska,[20] take their names from deposits of this mineral.

Structure

Galena belongs to the octahedral sulfide group of minerals that have metal ions in octahedral positions, such as the iron sulfide pyrrhotite and the nickel arsenide niccolite. The galena group is named after its most common member, with other isometric members that include manganese bearing alabandite and niningerite.[8] [4]

Divalent lead (Pb) cations and sulfur (S) anions form a close-packed cubic unit cell much like the mineral halite of the halide mineral group. Zinc, cadmium, iron, copper, antimony, arsenic, bismuth and selenium also occur in variable amounts in galena. Selenium substitutes for sulfur in the structure constituting a solid solution series. The lead telluride mineral altaite has the same crystal structure as galena.[8]

Geochemistry

Within the weathering or oxidation zone galena alters to anglesite (lead sulfate) or cerussite (lead carbonate).[8] Galena exposed to acid mine drainage can be oxidized to anglesite by naturally occurring bacteria and archaea, in a process similar to bioleaching.[21]

Uses

One of the oldest uses of galena was to produce kohl, an eye cosmetic now regarded as toxic due to the risk of lead poisoning.[22] In Ancient Egypt, this was applied around the eyes to reduce the glare of the desert sun and to repel flies, which were a potential source of disease.[23]

In pre-Columbian North America, galena was used by indigenous peoples as an ingredient in decorative paints and cosmetics, and widely traded throughout the eastern United States.[24] Traces of galena are frequently found at the Mississippian city at Kincaid Mounds in present-day Illinois.[25] The galena used at the site originated from deposits in southeastern and central Missouri and the Upper Mississippi Valley.

Galena is the primary ore of lead, and is often mined for its silver content.[6] It is used as a source of lead in ceramic glaze.[26]

Galena is a semiconductor with a small band gap of about 0.4 eV, which found use in early wireless communication systems. It was used as the crystal in crystal radio receivers, in which it was used as a point-contact diode capable of rectifying alternating current to detect the radio signals. The galena crystal was used with a sharp wire, known as a "cat's whisker", in contact with it.[27]

In modern times, galena is primarily used to extract its constituent minerals. In addition to silver, it is the most important source of lead, for uses such as in lead-acid batteries.[9]

See also

External links

Notes and References

  1. Warr. L.N.. 2021. IMA–CNMNC approved mineral symbols. Mineralogical Magazine. 85. 3. 291–320. 10.1180/mgm.2021.43. 2021MinM...85..291W. 235729616. free.
  2. Book: Anthony . John W. . Bideaux . Richard A. . Bladh . Kenneth W. . Nichols . Monte C. . Handbook of Mineralogy. Mineralogical Society of America. Chantilly, VA. Galena . 0962209708 . 1 . 1990.
  3. Web site: Galena . Webmineral.
  4. http://www.mindat.org/min-1641.html Galena
  5. Book: SME. 9780873352666. Young. Courtney A.. Patrick R.. Taylor . Corby G.. Anderson. Hydrometallurgy 2008: Proceedings of the Sixth International Symposium. 2008.
  6. Lucas . A. . Silver in Ancient Times . The Journal of Egyptian Archaeology . May 1928 . 14 . 1 . 313–319 . 10.1177/030751332801400160. 192277012 .
  7. Winder . C. . The history of lead – Part 3 . 1993b . 12 February 2016 . dead . https://web.archive.org/web/20070831200744/http://lead.org.au/lanv2n3/lanv2n3-22.html . 31 August 2007 . LEAD Action News . 2 . 3 . 1324-6011 .
  8. Book: Klein . Cornelis . Hurlbut . Cornelius S. Jr. . Manual of mineralogy (after James D. Dana) . 1993 . Wiley . New York . 047157452X . 21st . 354–356.
  9. Web site: Galena Mineral Uses and Properties . Hobart M. King . geology.com . 29 March 2024 .
  10. 10.11141/ia.56.9. Sending Laurion Back to the Future: Bronze Age Silver and the Source of Confusion. Wood. J. R.. Hsu. Y-T.. Bell. C.. Internet Archaeology. 2021. 56. 9. 236973111. free.
  11. Book: Calvo, Miguel . Minerales y Minas de España. Vol. II. Sulfuros y sulfosales. . Museo de Ciencias Naturales de Alava . 2003 . 84-7821-543-3 . Spain . 293-301 . es . Minerals and mines of Spain.
  12. Web site: Lead . Geoscience Australia . 4 March 2018 . Australian Government . 26 June 2021.
  13. Walters . Stephen . Bailey . Andrew . Geology and mineralization of the Cannington Ag-Pb-Zn deposit; an example of Broken Hill-type mineralization in the eastern succession, Mount Isa Inlier, Australia . Economic Geology . 1998-12-01 . 93 . 8 . 1307–1329 . 10.2113/gsecongeo.93.8.1307. 1998EcGeo..93.1307W .
  14. The largest crystals. American Mineralogist. 66. 885–907. 1981. Rickwood . P. C..
  15. Web site: Office of the Secretary of State, Missouri – State Symbols . 2009-11-12 . State of Missouri.
  16. Web site: Wisconsin State Symbols . 2009-11-12 . State of Wisconsin . dead . https://web.archive.org/web/20100112222837/http://www.wisconsin.gov/state/core/wisconsin_state_symbols.html . 2010-01-12 .
  17. Rydjord, John (1972) Kansas Place-Names, University of Oklahoma Press. p. 77
  18. Book: The Origin of Certain Place Names in the United States . Govt. Print. Off. . Gannett, Henry . 1905 . 133.
  19. Web site: Galena Historical Society. June 21, 2006. History Highlights. April 13, 2007.
  20. http://www.dec.state.ak.us/SPAR/CSP/sites/galena.htm state.ak.us
  21. 10.1016/j.hydromet.2004.07.001. Kinetics and mechanism of the bacterial and ferric sulphate oxidation of galena. 2004. Da Silva. Gabriel. Hydrometallurgy. 75. 1–4. 99–110. 2004HydMe..75...99D .
  22. Web site: Toxic trends . Wellcome Collection . 17 December 2019. 29 March 2024 .
  23. Book: Metropolitan Museum of Art . The Art of Medicine in Ancient Egypt . New York . 2005 . 10 . 1-58839-170-1.
  24. News: Lead pollution from Native Americans attributed to crushing galena for glitter paint, adornments . . 21 October 2019 . 11 January 2020.
  25. https://www.atlasobscura.com/articles/found-precolumbian-glitter-in-illinois The Glittery Legacy of Lead at a Historic Native American Site
  26. http://www.thepotteries.org/types/glaze.htm Glaze
  27. Lee. Thomas H.. [ftp://119.235.48.163/BIET/Materials/Journals/ECE/Solid-State_Circuits_Newslette/The_Pre-_History_of_the_Integrated_Circuit_A_Random_Walk-C9G.pdf The (Pre-)History of the Integrated Circuit: A Random Walk]. IEEE Solid-State Circuits Newsletter. 12. 2. 2007. 16–22. 1098-4232. 10.1109/N-SSC.2007.4785573. 17583856.