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Mineralogy

May 04, 2023

Mineralogy[n 1] is a subject of geology specializing in the scientific study of the chemistry, crystal structure, and physical (including optical) properties of minerals and mineralized artifacts. Specific studies within mineralogy include the processes of mineral origin and formation, classification of minerals, their geographical distribution, as well as their utilization.

Mineralogy applies principles of chemistry, geology, physics and materials science to the study of minerals

History

 
Page from Treatise on mineralogy by Friedrich Mohs (1825)
 
The Moon Mineralogy Mapper, a spectrometer that mapped the lunar surface[3]
Main article: History of mineralogy

Early writing on mineralogy, especially on gemstones, comes from ancient Babylonia, the ancient Greco-Roman world, ancient and medieval China, and Sanskrit texts from ancient India and the ancient Islamic world.[4] Books on the subject included the Naturalis Historia of Pliny the Elder, which not only described many different minerals but also explained many of their properties, and Kitab al Jawahir (Book of Precious Stones) by Persian scientist Al-Biruni. The German Renaissance specialist Georgius Agricola wrote works such as De re metallica (On Metals, 1556) and De Natura Fossilium (On the Nature of Rocks, 1546) which began the scientific approach to the subject. Systematic scientific studies of minerals and rocks developed in post-Renaissance Europe.[4] The modern study of mineralogy was founded on the principles of crystallography (the origins of geometric crystallography, itself, can be traced back to the mineralogy practiced in the eighteenth and nineteenth centuries) and to the microscopic study of rock sections with the invention of the microscope in the 17th century.[4]

Nicholas Steno first observed the law of constancy of interfacial angles (also known as the first law of crystallography) in quartz crystals in 1669.[5]: 4  This was later generalized and established experimentally by Jean-Baptiste L. Romé de l'Islee in 1783.[6] René Just Haüy, the "father of modern crystallography", showed that crystals are periodic and established that the orientations of crystal faces can be expressed in terms of rational numbers, as later encoded in the Miller indices.[5]: 4  In 1814, Jöns Jacob Berzelius introduced a classification of minerals based on their chemistry rather than their crystal structure.[7] William Nicol developed the Nicol prism, which polarizes light, in 1827–1828 while studying fossilized wood; Henry Clifton Sorby showed that thin sections of minerals could be identified by their optical properties using a polarizing microscope.[5]: 4 [7]: 15  James D. Dana published his first edition of A System of Mineralogy in 1837, and in a later edition introduced a chemical classification that is still the standard.[5]: 4 [7]: 15  X-ray diffraction was demonstrated by Max von Laue in 1912, and developed into a tool for analyzing the crystal structure of minerals by the father/son team of William Henry Bragg and William Lawrence Bragg.[5]: 4 

More recently, driven by advances in experimental technique (such as neutron diffraction) and available computational power, the latter of which has enabled extremely accurate atomic-scale simulations of the behaviour of crystals, the science has branched out to consider more general problems in the fields of inorganic chemistry and solid-state physics. It, however, retains a focus on the crystal structures commonly encountered in rock-forming minerals (such as the perovskites, clay minerals and framework silicates). In particular, the field has made great advances in the understanding of the relationship between the atomic-scale structure of minerals and their function; in nature, prominent examples would be accurate measurement and prediction of the elastic properties of minerals, which has led to new insight into seismological behaviour of rocks and depth-related discontinuities in seismograms of the Earth's mantle. To this end, in their focus on the connection between atomic-scale phenomena and macroscopic properties, the mineral sciences (as they are now commonly known) display perhaps more of an overlap with materials science than any other discipline.

Physical properties

 
Calcite is a carbonate mineral (CaCO3) with a rhombohedral crystal structure.
 
Aragonite is an orthorhombic polymorph of calcite.

An initial step in identifying a mineral is to examine its physical properties, many of which can be measured on a hand sample. These can be classified into density (often given as specific gravity); measures of mechanical cohesion (hardness, tenacity, cleavage, fracture, parting); macroscopic visual properties (luster, color, streak, luminescence, diaphaneity); magnetic and electric properties; radioactivity and solubility in hydrogen chloride (HCl).[5]: 97–113 [8]: 39–53 

Hardness is determined by comparison with other minerals. In the Mohs scale, a standard set of minerals are numbered in order of increasing hardness from 1 (talc) to 10 (diamond). A harder mineral will scratch a softer, so an unknown mineral can be placed in this scale, by which minerals; it scratches and which scratch it. A few minerals such as calcite and kyanite have a hardness that depends significantly on direction.[9]: 254–255  Hardness can also be measured on an absolute scale using a sclerometer; compared to the absolute scale, the Mohs scale is nonlinear.[8]: 52 

Tenacity refers to the way a mineral behaves, when it is broken, crushed, bent or torn. A mineral can be brittle, malleable, sectile, ductile, flexible or elastic. An important influence on tenacity is the type of chemical bond (e.g., ionic or metallic).[9]: 255–256 

Of the other measures of mechanical cohesion, cleavage is the tendency to break along certain crystallographic planes. It is described by the quality (e.g., perfect or fair) and the orientation of the plane in crystallographic nomenclature.

Parting is the tendency to break along planes of weakness due to pressure, twinning or exsolution. Where these two kinds of break do not occur, fracture is a less orderly form that may be conchoidal (having smooth curves resembling the interior of a shell), fibrous, splintery, hackly (jagged with sharp edges), or uneven.[9]: 253–254 

If the mineral is well crystallized, it will also have a distinctive crystal habit (for example, hexagonal, columnar, botryoidal) that reflects the crystal structure or internal arrangement of atoms.[8]: 40–41  It is also affected by crystal defects and twinning. Many crystals are polymorphic, having more than one possible crystal structure depending on factors such as pressure and temperature.[5]: 66–68 [8]: 126 

Crystal structure

 
The perovskite crystal structure. The most abundant mineral in the Earth, bridgmanite, has this structure.[10] Its chemical formula is (Mg,Fe)SiO3; the red spheres are oxygen, the blue spheres silicon and the green spheres magnesium or iron.
Main article: Crystal structure
See also: Crystallography

The crystal structure is the arrangement of atoms in a crystal. It is represented by a lattice of points which repeats a basic pattern, called a unit cell, in three dimensions. The lattice can be characterized by its symmetries and by the dimensions of the unit cell. These dimensions are represented by three Miller indices.[11]: 91–92  The lattice remains unchanged by certain symmetry operations about any given point in the lattice: reflection, rotation, inversion, and rotary inversion, a combination of rotation and reflection. Together, they make up a mathematical object called a crystallographic point group or crystal class. There are 32 possible crystal classes. In addition, there are operations that displace all the points: translation, screw axis, and glide plane. In combination with the point symmetries, they form 230 possible space groups.[11]: 125–126 

Most geology departments have X-ray powder diffraction equipment to analyze the crystal structures of minerals.[8]: 54–55  X-rays have wavelengths that are the same order of magnitude as the distances between atoms. Diffraction, the constructive and destructive interference between waves scattered at different atoms, leads to distinctive patterns of high and low intensity that depend on the geometry of the crystal. In a sample that is ground to a powder, the X-rays sample a random distribution of all crystal orientations.[12] Powder diffraction can distinguish between minerals that may appear the same in a hand sample, for example quartz and its polymorphs tridymite and cristobalite.[8]: 54 

Isomorphous minerals of different compositions have similar powder diffraction patterns, the main difference being in spacing and intensity of lines. For example, the NaCl (halite) crystal structure is space group Fm3m; this structure is shared by sylvite (KCl), periclase (MgO), bunsenite (NiO), galena (PbS), alabandite (MnS), chlorargyrite (AgCl), and osbornite (TiN).[9]: 150–151 

Chemical elements

See also: analytical chemistry
 
Portable Micro-X-ray fluorescence machine

A few minerals are chemical elements, including sulfur, copper, silver, and gold, but the vast majority are compounds. The classical method for identifying composition is wet chemical analysis, which involves dissolving a mineral in an acid such as hydrochloric acid (HCl). The elements in solution are then identified using colorimetry, volumetric analysis or gravimetric analysis.[9]: 224–225 

Since 1960, most chemistry analysis is done using instruments. One of these, atomic absorption spectroscopy, is similar to wet chemistry in that the sample must still be dissolved, but it is much faster and cheaper. The solution is vaporized and its absorption spectrum is measured in the visible and ultraviolet range.[9]: 225–226  Other techniques are X-ray fluorescence, electron microprobe analysis atom probe tomography and optical emission spectrography.[9]: 227–232 

Optical

 
Photomicrograph of olivine adcumulate from the Archaean komatiite of Agnew, Western Australia.
Main article: Optical mineralogy

In addition to macroscopic properties such as colour or lustre, minerals have properties that require a polarizing microscope to observe.

Transmitted light

When light passes from air or a vacuum into a transparent crystal, some of it is reflected at the surface and some refracted. The latter is a bending of the light path that occurs because the speed of light changes as it goes into the crystal; Snell's law relates the bending angle to the Refractive index, the ratio of speed in a vacuum to speed in the crystal. Crystals whose point symmetry group falls in the cubic system are isotropic: the index does not depend on direction. All other crystals are anisotropic: light passing through them is broken up into two plane polarized rays that travel at different speeds and refract at different angles.[9]: 289–291 

A polarizing microscope is similar to an ordinary microscope, but it has two plane-polarized filters, a (polarizer) below the sample and an analyzer above it, polarized perpendicular to each other. Light passes successively through the polarizer, the sample and the analyzer. If there is no sample, the analyzer blocks all the light from the polarizer. However, an anisotropic sample will generally change the polarization so some of the light can pass through. Thin sections and powders can be used as samples.[9]: 293–294 

When an isotropic crystal is viewed, it appears dark because it does not change the polarization of the light. However, when it is immersed in a calibrated liquid with a lower index of refraction and the microscope is thrown out of focus, a bright line called a Becke line appears around the perimeter of the crystal. By observing the presence or absence of such lines in liquids with different indices, the index of the crystal can be estimated, usually to within ± 0.003.[9]: 294–295 

Systematic

 
Hanksite, Na22K(SO4)9(CO3)2Cl, one of the few minerals that is considered a carbonate and a sulfate
See also: Mineral § Mineral classes

Systematic mineralogy is the identification and classification of minerals by their properties. Historically, mineralogy was heavily concerned with taxonomy of the rock-forming minerals. In 1959, the International Mineralogical Association formed the Commission of New Minerals and Mineral Names to rationalize the nomenclature and regulate the introduction of new names. In July 2006, it was merged with the Commission on Classification of Minerals to form the Commission on New Minerals, Nomenclature, and Classification.[13] There are over 6,000 named and unnamed minerals, and about 100 are discovered each year.[14] The Manual of Mineralogy places minerals in the following classes: native elements, sulfides, sulfosalts, oxides and hydroxides, halides, carbonates, nitrates and borates, sulfates, chromates, molybdates and tungstates, phosphates, arsenates and vanadates, and silicates.[9]

Formation environments

The environments of mineral formation and growth are highly varied, ranging from slow crystallization at the high temperatures and pressures of igneous melts deep within the Earth's crust to the low temperature precipitation from a saline brine at the Earth's surface.

Various possible methods of formation include:[15]

Biomineralogy

Biomineralogy is a cross-over field between mineralogy, paleontology and biology. It is the study of how plants and animals stabilize minerals under biological control, and the sequencing of mineral replacement of those minerals after deposition.[16] It uses techniques from chemical mineralogy, especially isotopic studies, to determine such things as growth forms in living plants and animals[17][18] as well as things like the original mineral content of fossils.[19]

A new approach to mineralogy called mineral evolution explores the co-evolution of the geosphere and biosphere, including the role of minerals in the origin of life and processes as mineral-catalyzed organic synthesis and the selective adsorption of organic molecules on mineral surfaces.[20][21]

Mineral ecology

In 2011, several researchers began to develop a Mineral Evolution Database.[22] This database integrates the crowd-sourced site Mindat.org, which has over 690,000 mineral-locality pairs, with the official IMA list of approved minerals and age data from geological publications.[23]

This database makes it possible to apply statistics to answer new questions, an approach that has been called mineral ecology. One such question is how much of mineral evolution is deterministic and how much the result of chance. Some factors are deterministic, such as the chemical nature of a mineral and conditions for its stability; but mineralogy can also be affected by the processes that determine a planet's composition. In a 2015 paper, Robert Hazen and others analyzed the number of minerals involving each element as a function of its abundance. They found that Earth, with over 4800 known minerals and 72 elements, has a power law relationship. The Moon, with only 63 minerals and 24 elements (based on a much smaller sample) has essentially the same relationship. This implies that, given the chemical composition of the planet, one could predict the more common minerals. However, the distribution has a long tail, with 34% of the minerals having been found at only one or two locations. The model predicts that thousands more mineral species may await discovery or have formed and then been lost to erosion, burial or other processes. This implies a role of chance in the formation of rare minerals occur.[24][25][26][27]

In another use of big data sets, network theory was applied to a dataset of carbon minerals, revealing new patterns in their diversity and distribution. The analysis can show which minerals tend to coexist and what conditions (geological, physical, chemical and biological) are associated with them. This information can be used to predict where to look for new deposits and even new mineral species.[28][29][30]

 
A color chart of some raw forms of commercially valuable metals.[31]

Uses

Minerals are essential to various needs within human society, such as minerals used as ores for essential components of metal products used in various commodities and machinery, essential components to building materials such as limestone, marble, granite, gravel, glass, plaster, cement, etc.[15] Minerals are also used in fertilizers to enrich the growth of agricultural crops.

 
A small collection of mineral samples, with cases. Labels in Russian.

Collecting

Mineral collecting is also a recreational study and collection hobby, with clubs and societies representing the field.[32][33] Museums, such as the Smithsonian National Museum of Natural History Hall of Geology, Gems, and Minerals, the Natural History Museum of Los Angeles County, the Carnegie Museum of Natural History, the Natural History Museum, London, and the private Mim Mineral Museum in Beirut, Lebanon,[34][35] have popular collections of mineral specimens on permanent display.[36]

See also

Notes

  1. ^ Commonly pronounced /ˌmɪnəˈrɒləi/[1][2] due to the common phonological process of anticipatory assimilation, especially in North-American but also in UK English. Nevertheless, even modern descriptive UK dictionaries tend to record only the spelling pronunciation /ˌmɪnəˈræləɪ/, sometimes even while their sound file instead has the assimilated pronunciation, as in the case of the Collins Dictionary.[2][failed verification]

References

  1. ^ "mineralogy". The American Heritage Dictionary of the English Language (5th ed.). HarperCollins. Retrieved 2017-10-19.
  2. ^ a b "mineralogy". CollinsDictionary.com. HarperCollins. Retrieved 2017-10-19.
  3. ^ . JPL. Archived from the original on 1 January 2009. Retrieved 19 December 2008.
  4. ^ a b c Needham, Joseph (1959). Science and civilisation in China. Cambridge: Cambridge University Press. pp. 637–638. ISBN 978-0521058018.
  5. ^ a b c d e f g Nesse, William D. (2012). Introduction to mineralogy (2nd ed.). New York: Oxford University Press. ISBN 978-0199827381.
  6. ^ "Law of the constancy of interfacial angles". Online dictionary of crystallography. International Union of Crystallography. 24 August 2014. from the original on 19 October 2016. Retrieved 22 September 2015.
  7. ^ a b c Rafferty, John P. (2012). Geological sciences (1st ed.). New York: Britannica Educational Pub. in association with Rosen Educational Services. pp. 14–15. ISBN 9781615304950.
  8. ^ a b c d e f Klein, Cornelis; Philpotts, Anthony R. (2013). Earth materials : introduction to mineralogy and petrology. New York: Cambridge University Press. ISBN 9780521145213.
  9. ^ a b c d e f g h i j k Klein, Cornelis; Hurlbut, Cornelius S. Jr. (1993). Manual of mineralogy : (after James D. Dana) (21st ed.). New York: Wiley. ISBN 047157452X.
  10. ^ Sharp, T. (27 November 2014). "Bridgmanite – named at last". Science. 346 (6213): 1057–1058. Bibcode:2014Sci...346.1057S. doi:10.1126/science.1261887. PMID 25430755. S2CID 206563252.
  11. ^ a b Ashcroft, Neil W.; Mermin, N. David (1977). Solid state physics (27. repr. ed.). New York: Holt, Rinehart and Winston. ISBN 9780030839931.
  12. ^ Dinnebier, Robert E.; Billinge, Simon J.L. (2008). "1. Principles of powder diffraction". In Dinnebier, Robert E.; Billinge, Simon J.L. (eds.). Powder diffraction : theory and practice (Repr. ed.). Cambridge: Royal Society of Chemistry. pp. 1–19. ISBN 9780854042319.
  13. ^ Parsons, Ian (October 2006). "International Mineralogical Association". Elements. 2 (6): 388. doi:10.2113/gselements.2.6.388.
  14. ^ Higgins, Michael D.; Smith, Dorian G. W. (October 2010). "A census of mineral species in 2010". Elements. 6 (5): 346.
  15. ^ a b Moses, Alfred J. (1918–1920). "Mineralogy". In Ramsdell, Lewis S. (ed.). Encyclopedia Americana: International Edition. Vol. 19. New York: Americana Corporation. pp. 164–168.
  16. ^ Scurfield, Gordon (1979). "Wood Petrifaction: an aspect of biomineralogy". Australian Journal of Botany. 27 (4): 377–390. doi:10.1071/bt9790377.
  17. ^ Christoffersen, M.R.; Balic-Zunic, T.; Pehrson, S.; Christoffersen, J. (2001). "Kinetics of Growth of Columnar Triclinic Calcium Pyrophosphate Dihydrate Crystals". Crystal Growth & Design. 1 (6): 463–466. doi:10.1021/cg015547j.
  18. ^ Chandrajith, R.; Wijewardana, G.; Dissanayake, C.B.; Abeygunasekara, A. (2006). "Biomineralogy of human urinary calculi (kidney stones) from some geographic regions of Sri Lanka". Environmental Geochemistry and Health. 28 (4): 393–399. doi:10.1007/s10653-006-9048-y. PMID 16791711. S2CID 24627795.
  19. ^ Lowenstam, Heitz A (1954). "Environmental relations of modification compositions of certain carbonate secreting marine invertebrates". Proceedings of the National Academy of Sciences of the United States of America. 40 (1): 39–48. Bibcode:1954PNAS...40...39L. doi:10.1073/pnas.40.1.39. PMC 527935. PMID 16589423. from the original on 2015-10-16. Retrieved 2017-07-04.
  20. ^ Amos, Jonathan (13 February 2016). "Earth's rarest minerals catalogued". BBC News. from the original on 23 November 2018. Retrieved 17 September 2016.
  21. ^ Hazen, Robert M.; Papineau, Dominic; Bleeker, Wouter; Downs, Robert T.; Ferry, John M.; et al. (November–December 2008). "Mineral Evolution". American Mineralogist. 93 (11–12): 1693–1720. Bibcode:2008AmMin..93.1693H. doi:10.2138/am.2008.2955. S2CID 27460479.
  22. ^ Hazen, R. M.; Bekker, A.; Bish, D. L.; Bleeker, W.; Downs, R. T.; Farquhar, J.; Ferry, J. M.; Grew, E. S.; Knoll, A. H.; Papineau, D.; Ralph, J. P.; Sverjensky, D. A.; Valley, J. W. (24 June 2011). "Needs and opportunities in mineral evolution research". American Mineralogist. 96 (7): 953–963. Bibcode:2011AmMin..96..953H. doi:10.2138/am.2011.3725. S2CID 21530264.
  23. ^ Golden, Joshua; Pires, Alexander J.; Hazenj, Robert M.; Downs, Robert T.; Ralph, Jolyon; Meyer, Michael Bruce (2016). Building the mineral evolution database: implications for future big data analysis. GSA Annual Meeting. Denver, Colorado. doi:10.1130/abs/2016AM-286024.
  24. ^ Hazen, Robert M.; Grew, Edward S.; Downs, Robert T.; Golden, Joshua; Hystad, Grethe (March 2015). "Mineral ecology: Chance and necessity in the mineral diversity of terrestrial planets". The Canadian Mineralogist. 53 (2): 295–324. doi:10.3749/canmin.1400086. S2CID 10969988.
  25. ^ Hazen, Robert. "Mineral Ecology". Carnegie Science. from the original on 28 May 2018. Retrieved 15 May 2018.
  26. ^ Kwok, Roberta (11 August 2015). "Is Mineral Evolution Driven by Chance?". Quanta Magazine. from the original on 26 August 2018. Retrieved 11 August 2018.
  27. ^ Kwok, Roberta (16 August 2015). "How Life and Luck Changed Earth's Minerals". Wired. from the original on 17 July 2017. Retrieved 24 August 2018.
  28. ^ Oleson, Timothy (1 May 2018). "Data-driven discovery reveals Earth's missing minerals". Earth Magazine. American Geosciences Institute. from the original on 23 August 2018. Retrieved 26 August 2018.
  29. ^ Hooper, Joel (2 August 2017). "Data mining: How digging through big data can turn up new". Cosmos. from the original on 26 August 2018. Retrieved 26 August 2018.
  30. ^ Rogers, Nala (1 August 2017). "How Math Can Help Geologists Discover New Minerals". Inside Science. from the original on 27 August 2018. Retrieved 26 August 2018.
  31. ^ The Encyclopedia Americana. New York: Encyclopedia Americana Corp. 1918–1920. plate opposite p. 166.
  32. ^ "Collector's Corner". The Mineralogical Society of America. from the original on 2010-06-19. Retrieved 2010-05-22.
  33. ^ "The American Federation of Mineral Societies". from the original on 2017-07-22. Retrieved 2010-05-22.
  34. ^ Wilson, W (2013). "The Opening of the Mim Mineral Museum in Beirut, Lebanon". The Mineralogical Record. 45 (1): 61–83.
  35. ^ Lyckberg, Peter (16 October 2013). "The MIM Museum opening, Lebanon". Mindat.org. from the original on 26 October 2013. Retrieved 19 October 2017.
  36. ^ "Gems and Minerals". Natural History Museum of Los Angeles. from the original on 2010-05-31. Retrieved 2010-05-22.

Further reading

  • Gribble, C.D.; Hall, A.J. (1993). Optical Mineralogy: Principles And Practice. London: CRC Press. ISBN 9780203498705.
  • Harrell, James A. (2012). "Mineralogy". In Bagnall, Roger S.; Brodersen, Kai; Champion, Craige B.; Erskine, Andrew (eds.). The encyclopedia of ancient history. Malden, MA: Wiley-Blackwell. doi:10.1002/9781444338386.wbeah21217. ISBN 9781444338386.
  • Hazen, Robert M. (1984). "Mineralogy: A historical review" (PDF). Journal of Geological Education. 32 (5): 288–298. Bibcode:1984JGeoE..32..288H. doi:10.5408/0022-1368-32.5.288. (PDF) from the original on 28 September 2017. Retrieved 27 September 2017.
  • Laudan, Rachel (1993). From mineralogy to geology : the foundations of a science, 1650-1830 (Pbk. ed.). Chicago: University of Chicago Press. ISBN 9780226469478.
  • Oldroyd, David (1998). Sciences of the earth : studies in the history of mineralogy and geology. Aldershot: Ashgate. ISBN 9780860787709.
  • Perkins, Dexter (2014). Mineralogy. Pearson Higher Ed. ISBN 9780321986573.
  • Rapp, George R. (2002). Archaeomineralogy. Berlin, Heidelberg: Springer Berlin Heidelberg. ISBN 9783662050057.
  • Tisljar, S.K. Haldar, Josip (2013). Introduction to mineralogy and petrology. Burlington: Elsevier Science. ISBN 9780124167100.
  • Wenk, Hans-Rudolf; Bulakh, Andrey (2016). Minerals: Their Constitution and Origin. Cambridge University Press. ISBN 9781316425282.
  • Whewell, William (2010). "Book XV. History of Mineralogy". History of the Inductive Sciences: From the Earliest to the Present Times. Cambridge University Press. pp. 187–252. ISBN 9781108019262.

External links

 
Wikimedia Commons has media related to Mineralogy.
 
Wikisource has original works on the topic: Mineralogy
  • The Virtual Museum of the History of Mineralogy

Associations

  • American Federation of Mineral Societies
  • French Society of Mineralogy and Crystallography
  • German Mineralogical Society
  • International Mineralogical Association
  • Italian Mineralogical and Petrological Society
  • Mineralogical Association of Canada
  • Mineralogical Society of Great Britain and Ireland
  • Mineralogical Society of America

May 04, 2023
mineralogy, subject, geology, specializing, scientific, study, chemistry, crystal, structure, physical, including, optical, properties, minerals, mineralized, artifacts, specific, studies, within, mineralogy, include, processes, mineral, origin, formation, cla. Mineralogy n 1 is a subject of geology specializing in the scientific study of the chemistry crystal structure and physical including optical properties of minerals and mineralized artifacts Specific studies within mineralogy include the processes of mineral origin and formation classification of minerals their geographical distribution as well as their utilization Mineralogy applies principles of chemistry geology physics and materials science to the study of minerals Contents 1 History 2 Physical properties 3 Crystal structure 4 Chemical elements 5 Optical 5 1 Transmitted light 6 Systematic 7 Formation environments 8 Biomineralogy 9 Mineral ecology 10 Uses 10 1 Collecting 11 See also 12 Notes 13 References 14 Further reading 15 External links 15 1 AssociationsHistory Edit Page from Treatise on mineralogy by Friedrich Mohs 1825 The Moon Mineralogy Mapper a spectrometer that mapped the lunar surface 3 Main article History of mineralogy Early writing on mineralogy especially on gemstones comes from ancient Babylonia the ancient Greco Roman world ancient and medieval China and Sanskrit texts from ancient India and the ancient Islamic world 4 Books on the subject included the Naturalis Historia of Pliny the Elder which not only described many different minerals but also explained many of their properties and Kitab al Jawahir Book of Precious Stones by Persian scientist Al Biruni The German Renaissance specialist Georgius Agricola wrote works such as De re metallica On Metals 1556 and De Natura Fossilium On the Nature of Rocks 1546 which began the scientific approach to the subject Systematic scientific studies of minerals and rocks developed in post Renaissance Europe 4 The modern study of mineralogy was founded on the principles of crystallography the origins of geometric crystallography itself can be traced back to the mineralogy practiced in the eighteenth and nineteenth centuries and to the microscopic study of rock sections with the invention of the microscope in the 17th century 4 Nicholas Steno first observed the law of constancy of interfacial angles also known as the first law of crystallography in quartz crystals in 1669 5 4 This was later generalized and established experimentally by Jean Baptiste L Rome de l Islee in 1783 6 Rene Just Hauy the father of modern crystallography showed that crystals are periodic and established that the orientations of crystal faces can be expressed in terms of rational numbers as later encoded in the Miller indices 5 4 In 1814 Jons Jacob Berzelius introduced a classification of minerals based on their chemistry rather than their crystal structure 7 William Nicol developed the Nicol prism which polarizes light in 1827 1828 while studying fossilized wood Henry Clifton Sorby showed that thin sections of minerals could be identified by their optical properties using a polarizing microscope 5 4 7 15 James D Dana published his first edition of A System of Mineralogy in 1837 and in a later edition introduced a chemical classification that is still the standard 5 4 7 15 X ray diffraction was demonstrated by Max von Laue in 1912 and developed into a tool for analyzing the crystal structure of minerals by the father son team of William Henry Bragg and William Lawrence Bragg 5 4 More recently driven by advances in experimental technique such as neutron diffraction and available computational power the latter of which has enabled extremely accurate atomic scale simulations of the behaviour of crystals the science has branched out to consider more general problems in the fields of inorganic chemistry and solid state physics It however retains a focus on the crystal structures commonly encountered in rock forming minerals such as the perovskites clay minerals and framework silicates In particular the field has made great advances in the understanding of the relationship between the atomic scale structure of minerals and their function in nature prominent examples would be accurate measurement and prediction of the elastic properties of minerals which has led to new insight into seismological behaviour of rocks and depth related discontinuities in seismograms of the Earth s mantle To this end in their focus on the connection between atomic scale phenomena and macroscopic properties the mineral sciences as they are now commonly known display perhaps more of an overlap with materials science than any other discipline Physical properties Edit Calcite is a carbonate mineral CaCO3 with a rhombohedral crystal structure Aragonite is an orthorhombic polymorph of calcite An initial step in identifying a mineral is to examine its physical properties many of which can be measured on a hand sample These can be classified into density often given as specific gravity measures of mechanical cohesion hardness tenacity cleavage fracture parting macroscopic visual properties luster color streak luminescence diaphaneity magnetic and electric properties radioactivity and solubility in hydrogen chloride HCl 5 97 113 8 39 53 Hardness is determined by comparison with other minerals In the Mohs scale a standard set of minerals are numbered in order of increasing hardness from 1 talc to 10 diamond A harder mineral will scratch a softer so an unknown mineral can be placed in this scale by which minerals it scratches and which scratch it A few minerals such as calcite and kyanite have a hardness that depends significantly on direction 9 254 255 Hardness can also be measured on an absolute scale using a sclerometer compared to the absolute scale the Mohs scale is nonlinear 8 52 Tenacity refers to the way a mineral behaves when it is broken crushed bent or torn A mineral can be brittle malleable sectile ductile flexible or elastic An important influence on tenacity is the type of chemical bond e g ionic or metallic 9 255 256 Of the other measures of mechanical cohesion cleavage is the tendency to break along certain crystallographic planes It is described by the quality e g perfect or fair and the orientation of the plane in crystallographic nomenclature Parting is the tendency to break along planes of weakness due to pressure twinning or exsolution Where these two kinds of break do not occur fracture is a less orderly form that may be conchoidal having smooth curves resembling the interior of a shell fibrous splintery hackly jagged with sharp edges or uneven 9 253 254 If the mineral is well crystallized it will also have a distinctive crystal habit for example hexagonal columnar botryoidal that reflects the crystal structure or internal arrangement of atoms 8 40 41 It is also affected by crystal defects and twinning Many crystals are polymorphic having more than one possible crystal structure depending on factors such as pressure and temperature 5 66 68 8 126 Crystal structure Edit The perovskite crystal structure The most abundant mineral in the Earth bridgmanite has this structure 10 Its chemical formula is Mg Fe SiO3 the red spheres are oxygen the blue spheres silicon and the green spheres magnesium or iron Main article Crystal structure See also Crystallography The crystal structure is the arrangement of atoms in a crystal It is represented by a lattice of points which repeats a basic pattern called a unit cell in three dimensions The lattice can be characterized by its symmetries and by the dimensions of the unit cell These dimensions are represented by three Miller indices 11 91 92 The lattice remains unchanged by certain symmetry operations about any given point in the lattice reflection rotation inversion and rotary inversion a combination of rotation and reflection Together they make up a mathematical object called a crystallographic point group or crystal class There are 32 possible crystal classes In addition there are operations that displace all the points translation screw axis and glide plane In combination with the point symmetries they form 230 possible space groups 11 125 126 Most geology departments have X ray powder diffraction equipment to analyze the crystal structures of minerals 8 54 55 X rays have wavelengths that are the same order of magnitude as the distances between atoms Diffraction the constructive and destructive interference between waves scattered at different atoms leads to distinctive patterns of high and low intensity that depend on the geometry of the crystal In a sample that is ground to a powder the X rays sample a random distribution of all crystal orientations 12 Powder diffraction can distinguish between minerals that may appear the same in a hand sample for example quartz and its polymorphs tridymite and cristobalite 8 54 Isomorphous minerals of different compositions have similar powder diffraction patterns the main difference being in spacing and intensity of lines For example the NaCl halite crystal structure is space group Fm3m this structure is shared by sylvite KCl periclase MgO bunsenite NiO galena PbS alabandite MnS chlorargyrite AgCl and osbornite TiN 9 150 151 Chemical elements EditSee also analytical chemistry Portable Micro X ray fluorescence machine A few minerals are chemical elements including sulfur copper silver and gold but the vast majority are compounds The classical method for identifying composition is wet chemical analysis which involves dissolving a mineral in an acid such as hydrochloric acid HCl The elements in solution are then identified using colorimetry volumetric analysis or gravimetric analysis 9 224 225 Since 1960 most chemistry analysis is done using instruments One of these atomic absorption spectroscopy is similar to wet chemistry in that the sample must still be dissolved but it is much faster and cheaper The solution is vaporized and its absorption spectrum is measured in the visible and ultraviolet range 9 225 226 Other techniques are X ray fluorescence electron microprobe analysis atom probe tomography and optical emission spectrography 9 227 232 Optical Edit Photomicrograph of olivine adcumulate from the Archaean komatiite of Agnew Western Australia Main article Optical mineralogy In addition to macroscopic properties such as colour or lustre minerals have properties that require a polarizing microscope to observe Transmitted light Edit When light passes from air or a vacuum into a transparent crystal some of it is reflected at the surface and some refracted The latter is a bending of the light path that occurs because the speed of light changes as it goes into the crystal Snell s law relates the bending angle to the Refractive index the ratio of speed in a vacuum to speed in the crystal Crystals whose point symmetry group falls in the cubic system are isotropic the index does not depend on direction All other crystals are anisotropic light passing through them is broken up into two plane polarized rays that travel at different speeds and refract at different angles 9 289 291 A polarizing microscope is similar to an ordinary microscope but it has two plane polarized filters a polarizer below the sample and an analyzer above it polarized perpendicular to each other Light passes successively through the polarizer the sample and the analyzer If there is no sample the analyzer blocks all the light from the polarizer However an anisotropic sample will generally change the polarization so some of the light can pass through Thin sections and powders can be used as samples 9 293 294 When an isotropic crystal is viewed it appears dark because it does not change the polarization of the light However when it is immersed in a calibrated liquid with a lower index of refraction and the microscope is thrown out of focus a bright line called a Becke line appears around the perimeter of the crystal By observing the presence or absence of such lines in liquids with different indices the index of the crystal can be estimated usually to within 0 003 9 294 295 Systematic Edit Hanksite Na22K SO4 9 CO3 2Cl one of the few minerals that is considered a carbonate and a sulfate See also Mineral Mineral classes Systematic mineralogy is the identification and classification of minerals by their properties Historically mineralogy was heavily concerned with taxonomy of the rock forming minerals In 1959 the International Mineralogical Association formed the Commission of New Minerals and Mineral Names to rationalize the nomenclature and regulate the introduction of new names In July 2006 it was merged with the Commission on Classification of Minerals to form the Commission on New Minerals Nomenclature and Classification 13 There are over 6 000 named and unnamed minerals and about 100 are discovered each year 14 The Manual of Mineralogy places minerals in the following classes native elements sulfides sulfosalts oxides and hydroxides halides carbonates nitrates and borates sulfates chromates molybdates and tungstates phosphates arsenates and vanadates and silicates 9 Formation environments EditThe environments of mineral formation and growth are highly varied ranging from slow crystallization at the high temperatures and pressures of igneous melts deep within the Earth s crust to the low temperature precipitation from a saline brine at the Earth s surface Various possible methods of formation include 15 sublimation from volcanic gases deposition from aqueous solutions and hydrothermal brines crystallization from an igneous magma or lava recrystallization due to metamorphic processes and metasomatism crystallization during diagenesis of sediments formation by oxidation and weathering of rocks exposed to the atmosphere or within the soil environment Biomineralogy EditBiomineralogy is a cross over field between mineralogy paleontology and biology It is the study of how plants and animals stabilize minerals under biological control and the sequencing of mineral replacement of those minerals after deposition 16 It uses techniques from chemical mineralogy especially isotopic studies to determine such things as growth forms in living plants and animals 17 18 as well as things like the original mineral content of fossils 19 A new approach to mineralogy called mineral evolution explores the co evolution of the geosphere and biosphere including the role of minerals in the origin of life and processes as mineral catalyzed organic synthesis and the selective adsorption of organic molecules on mineral surfaces 20 21 Mineral ecology EditIn 2011 several researchers began to develop a Mineral Evolution Database 22 This database integrates the crowd sourced site Mindat org which has over 690 000 mineral locality pairs with the official IMA list of approved minerals and age data from geological publications 23 This database makes it possible to apply statistics to answer new questions an approach that has been called mineral ecology One such question is how much of mineral evolution is deterministic and how much the result of chance Some factors are deterministic such as the chemical nature of a mineral and conditions for its stability but mineralogy can also be affected by the processes that determine a planet s composition In a 2015 paper Robert Hazen and others analyzed the number of minerals involving each element as a function of its abundance They found that Earth with over 4800 known minerals and 72 elements has a power law relationship The Moon with only 63 minerals and 24 elements based on a much smaller sample has essentially the same relationship This implies that given the chemical composition of the planet one could predict the more common minerals However the distribution has a long tail with 34 of the minerals having been found at only one or two locations The model predicts that thousands more mineral species may await discovery or have formed and then been lost to erosion burial or other processes This implies a role of chance in the formation of rare minerals occur 24 25 26 27 In another use of big data sets network theory was applied to a dataset of carbon minerals revealing new patterns in their diversity and distribution The analysis can show which minerals tend to coexist and what conditions geological physical chemical and biological are associated with them This information can be used to predict where to look for new deposits and even new mineral species 28 29 30 A color chart of some raw forms of commercially valuable metals 31 Uses EditMinerals are essential to various needs within human society such as minerals used as ores for essential components of metal products used in various commodities and machinery essential components to building materials such as limestone marble granite gravel glass plaster cement etc 15 Minerals are also used in fertilizers to enrich the growth of agricultural crops A small collection of mineral samples with cases Labels in Russian Collecting Edit Mineral collecting is also a recreational study and collection hobby with clubs and societies representing the field 32 33 Museums such as the Smithsonian National Museum of Natural History Hall of Geology Gems and Minerals the Natural History Museum of Los Angeles County the Carnegie Museum of Natural History the Natural History Museum London and the private Mim Mineral Museum in Beirut Lebanon 34 35 have popular collections of mineral specimens on permanent display 36 See also Edit Earth sciences portalList of minerals List of minerals recognized by the International Mineralogical Association List of mineralogists List of publications in mineralogy Mineral collecting Mineral physics Metallurgy PetrologyNotes Edit Commonly pronounced ˌ m ɪ n e ˈ r ɒ l e dʒ i 1 2 due to the common phonological process of anticipatory assimilation especially in North American but also in UK English Nevertheless even modern descriptive UK dictionaries tend to record only the spelling pronunciation ˌ m ɪ n e ˈ r ae l e dʒ ɪ sometimes even while their sound file instead has the assimilated pronunciation as in the case of the Collins Dictionary 2 failed verification References Edit mineralogy The American Heritage Dictionary of the English Language 5th ed HarperCollins Retrieved 2017 10 19 a b mineralogy CollinsDictionary com HarperCollins Retrieved 2017 10 19 NASA Instrument Inaugurates 3 D Moon Imaging JPL Archived from the original on 1 January 2009 Retrieved 19 December 2008 a b c Needham Joseph 1959 Science and civilisation in China Cambridge Cambridge University Press pp 637 638 ISBN 978 0521058018 a b c d e f g Nesse William D 2012 Introduction to mineralogy 2nd ed New York Oxford University Press ISBN 978 0199827381 Law of the constancy of interfacial angles Online dictionary of crystallography International Union of Crystallography 24 August 2014 Archived from the original on 19 October 2016 Retrieved 22 September 2015 a b c Rafferty John P 2012 Geological sciences 1st ed New York Britannica Educational Pub in association with Rosen Educational Services pp 14 15 ISBN 9781615304950 a b c d e f Klein Cornelis Philpotts Anthony R 2013 Earth materials introduction to mineralogy and petrology New York Cambridge University Press ISBN 9780521145213 a b c d e f g h i j k Klein Cornelis Hurlbut Cornelius S Jr 1993 Manual of mineralogy after James D Dana 21st ed New York Wiley ISBN 047157452X Sharp T 27 November 2014 Bridgmanite named at last Science 346 6213 1057 1058 Bibcode 2014Sci 346 1057S doi 10 1126 science 1261887 PMID 25430755 S2CID 206563252 a b Ashcroft Neil W Mermin N David 1977 Solid state physics 27 repr ed New York Holt Rinehart and Winston ISBN 9780030839931 Dinnebier Robert E Billinge Simon J L 2008 1 Principles of powder diffraction In Dinnebier Robert E Billinge Simon J L eds Powder diffraction theory and practice Repr ed Cambridge Royal Society of Chemistry pp 1 19 ISBN 9780854042319 Parsons Ian October 2006 International Mineralogical Association Elements 2 6 388 doi 10 2113 gselements 2 6 388 Higgins Michael D Smith Dorian G W October 2010 A census of mineral species in 2010 Elements 6 5 346 a b Moses Alfred J 1918 1920 Mineralogy In Ramsdell Lewis S ed Encyclopedia Americana International Edition Vol 19 New York Americana Corporation pp 164 168 Scurfield Gordon 1979 Wood Petrifaction an aspect of biomineralogy Australian Journal of Botany 27 4 377 390 doi 10 1071 bt9790377 Christoffersen M R Balic Zunic T Pehrson S Christoffersen J 2001 Kinetics of Growth of Columnar Triclinic Calcium Pyrophosphate Dihydrate Crystals Crystal Growth amp Design 1 6 463 466 doi 10 1021 cg015547j Chandrajith R Wijewardana G Dissanayake C B Abeygunasekara A 2006 Biomineralogy of human urinary calculi kidney stones from some geographic regions of Sri Lanka Environmental Geochemistry and Health 28 4 393 399 doi 10 1007 s10653 006 9048 y PMID 16791711 S2CID 24627795 Lowenstam Heitz A 1954 Environmental relations of modification compositions of certain carbonate secreting marine invertebrates Proceedings of the National Academy of Sciences of the United States of America 40 1 39 48 Bibcode 1954PNAS 40 39L doi 10 1073 pnas 40 1 39 PMC 527935 PMID 16589423 Archived from the original on 2015 10 16 Retrieved 2017 07 04 Amos Jonathan 13 February 2016 Earth s rarest minerals catalogued BBC News Archived from the original on 23 November 2018 Retrieved 17 September 2016 Hazen Robert M Papineau Dominic Bleeker Wouter Downs Robert T Ferry John M et al November December 2008 Mineral Evolution American Mineralogist 93 11 12 1693 1720 Bibcode 2008AmMin 93 1693H doi 10 2138 am 2008 2955 S2CID 27460479 Hazen R M Bekker A Bish D L Bleeker W Downs R T Farquhar J Ferry J M Grew E S Knoll A H Papineau D Ralph J P Sverjensky D A Valley J W 24 June 2011 Needs and opportunities in mineral evolution research American Mineralogist 96 7 953 963 Bibcode 2011AmMin 96 953H doi 10 2138 am 2011 3725 S2CID 21530264 Golden Joshua Pires Alexander J Hazenj Robert M Downs Robert T Ralph Jolyon Meyer Michael Bruce 2016 Building the mineral evolution database implications for future big data analysis GSA Annual Meeting Denver Colorado doi 10 1130 abs 2016AM 286024 Hazen Robert M Grew Edward S Downs Robert T Golden Joshua Hystad Grethe March 2015 Mineral ecology Chance and necessity in the mineral diversity of terrestrial planets The Canadian Mineralogist 53 2 295 324 doi 10 3749 canmin 1400086 S2CID 10969988 Hazen Robert Mineral Ecology Carnegie Science Archived from the original on 28 May 2018 Retrieved 15 May 2018 Kwok Roberta 11 August 2015 Is Mineral Evolution Driven by Chance Quanta Magazine Archived from the original on 26 August 2018 Retrieved 11 August 2018 Kwok Roberta 16 August 2015 How Life and Luck Changed Earth s Minerals Wired Archived from the original on 17 July 2017 Retrieved 24 August 2018 Oleson Timothy 1 May 2018 Data driven discovery reveals Earth s missing minerals Earth Magazine American Geosciences Institute Archived from the original on 23 August 2018 Retrieved 26 August 2018 Hooper Joel 2 August 2017 Data mining How digging through big data can turn up new Cosmos Archived from the original on 26 August 2018 Retrieved 26 August 2018 Rogers Nala 1 August 2017 How Math Can Help Geologists Discover New Minerals Inside Science Archived from the original on 27 August 2018 Retrieved 26 August 2018 The Encyclopedia Americana New York Encyclopedia Americana Corp 1918 1920 plate opposite p 166 Collector s Corner The Mineralogical Society of America Archived from the original on 2010 06 19 Retrieved 2010 05 22 The American Federation of Mineral Societies Archived from the original on 2017 07 22 Retrieved 2010 05 22 Wilson W 2013 The Opening of the Mim Mineral Museum in Beirut Lebanon The Mineralogical Record 45 1 61 83 Lyckberg Peter 16 October 2013 The MIM Museum opening Lebanon Mindat org Archived from the original on 26 October 2013 Retrieved 19 October 2017 Gems and Minerals Natural History Museum of Los Angeles Archived from the original on 2010 05 31 Retrieved 2010 05 22 Further reading EditGribble C D Hall A J 1993 Optical Mineralogy Principles And Practice London CRC Press ISBN 9780203498705 Harrell James A 2012 Mineralogy In Bagnall Roger S Brodersen Kai Champion Craige B Erskine Andrew eds The encyclopedia of ancient history Malden MA Wiley Blackwell doi 10 1002 9781444338386 wbeah21217 ISBN 9781444338386 Hazen Robert M 1984 Mineralogy A historical review PDF Journal of Geological Education 32 5 288 298 Bibcode 1984JGeoE 32 288H doi 10 5408 0022 1368 32 5 288 Archived PDF from the original on 28 September 2017 Retrieved 27 September 2017 Laudan Rachel 1993 From mineralogy to geology the foundations of a science 1650 1830 Pbk ed Chicago University of Chicago Press ISBN 9780226469478 Oldroyd David 1998 Sciences of the earth studies in the history of mineralogy and geology Aldershot Ashgate ISBN 9780860787709 Perkins Dexter 2014 Mineralogy Pearson Higher Ed ISBN 9780321986573 Rapp George R 2002 Archaeomineralogy Berlin Heidelberg Springer Berlin Heidelberg ISBN 9783662050057 Tisljar S K Haldar Josip 2013 Introduction to mineralogy and petrology Burlington Elsevier Science ISBN 9780124167100 Wenk Hans Rudolf Bulakh Andrey 2016 Minerals Their Constitution and Origin Cambridge University Press ISBN 9781316425282 Whewell William 2010 Book XV History of Mineralogy History of the Inductive Sciences From the Earliest to the Present Times Cambridge University Press pp 187 252 ISBN 9781108019262 External links Edit Wikimedia Commons has media related to Mineralogy Wikisource has original works on the topic Mineralogy The Virtual Museum of the History of MineralogyAssociations Edit American Federation of Mineral Societies French Society of Mineralogy and Crystallography Geological Society of America German Mineralogical Society International Mineralogical Association Italian Mineralogical and Petrological Society Mineralogical Association of Canada Mineralogical Society of Great Britain and Ireland Mineralogical Society of America Retrieved from https en wikipedia org w index php title Mineralogy amp oldid 1146924515, wikipedia, wiki, book, books, library,

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