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Hematite

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Hematite
Brazilian trigonal hematite crystal
General
CategoryOxide minerals
Formula
(repeating unit)
iron(III) oxide, Fe2O3, α-Fe2O3[1]
IMA symbolHem[2]
Strunz classification4.CB.05
Dana classification4.3.1.2
Crystal systemTrigonal
Crystal classHexagonal scalenohedral (3m)
H–M symbol: (3 2/m)
Space groupR3c (no. 167)
Unit cella = 5.038(2) Å;
c = 13.772(12) Å; Z = 6
Identification
ColorMetallic grey, dull to bright "rust-red" in earthy, compact, fine-grained material, steel-grey to black in crystals and massively crystalline ores
Crystal habitTabular to thick crystals; micaceous or platy, commonly in rosettes; radiating fibrous, reniform, botryoidal or stalactitic masses, columnar; earthy, granular, oolitic
TwinningPenetration and lamellar
CleavageNone, may show partings on {0001} and {1011}
FractureUneven to subconchoidal
TenacityBrittle
Mohs scale hardness5.5–6.5
LusterMetallic to splendent
StreakBright red to dark red
DiaphaneityOpaque
Specific gravity5.26
Density5.3
Optical propertiesUniaxial (−)
Refractive indexnω = 3.150–3.220, nε = 2.870–2.940
Birefringenceδ = 0.280
PleochroismO: brownish red; E: yellowish red
References[3][4][5]

Hematite (/ˈhməˌtt, ˈhɛmə-/), also spelled as haematite, is a common iron oxide compound with the formula, Fe2O3 and is widely found in rocks and soils.[6] Hematite crystals belong to the rhombohedral lattice system which is designated the alpha polymorph of Fe
2
O
3
. It has the same crystal structure as corundum (Al
2
O
3
) and ilmenite (FeTiO
3
). With this it forms a complete solid solution at temperatures above 950 °C (1,740 °F).

Hematite occurs naturally in black to steel or silver-gray, brown to reddish-brown, or red colors. It is mined as an important ore mineral of iron. It is electrically conductive.[7] Hematite varieties include kidney ore, martite (pseudomorphs after magnetite), iron rose and specularite (specular hematite). While these forms vary, they all have a rust-red streak. Hematite is not only harder than pure iron, but also much more brittle. Maghemite is a polymorph of hematite (γ-Fe
2
O
3
) with the same chemical formula, but with a spinel structure like magnetite.

Large deposits of hematite are found in banded iron formations. Gray hematite is typically found in places that have still, standing water, or mineral hot springs, such as those in Yellowstone National Park in North America. The mineral may precipitate in the water and collect in layers at the bottom of the lake, spring, or other standing water. Hematite can also occur in the absence of water, usually as the result of volcanic activity.

Clay-sized hematite crystals also may occur as a secondary mineral formed by weathering processes in soil, and along with other iron oxides or oxyhydroxides such as goethite, which is responsible for the red color of many tropical, ancient, or otherwise highly weathered soils.

Etymology and history

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The name hematite is derived from the Greek word for blood, αἷμα (haima), due to the red coloration found in some varieties of hematite.[6] The color of hematite is often used as a pigment. The English name of the stone is derived from Middle French hématite pierre, which was taken from Latin lapis haematites c. the 15th century, which originated from Ancient Greek αἱματίτης λίθος (haimatitēs lithos, "blood-red stone").

Ochre is a clay that is colored by varying amounts of hematite, varying between 20% and 70%.[8] Red ochre contains unhydrated hematite, whereas yellow ochre contains hydrated hematite (Fe2O3 · H2O). The principal use of ochre is for tinting with a permanent color.[8]

Use of the red chalk of this iron-oxide mineral in writing, drawing, and decoration is among the earliest in human history. To date, the earliest known human use of the powdery mineral is 164,000 years ago by the inhabitants of the Pinnacle Point caves in what now is South Africa, possibly for social purposes.[9] Hematite residues are also found in graves from 80,000 years ago. Near Rydno in Poland and Lovas in Hungary red chalk mines have been found that are from 5000 BC, belonging to the Linear Pottery culture at the Upper Rhine.[10]

Rich deposits of hematite have been found on the island of Elba that have been mined since the time of the Etruscans.[11]

Underground hematite mining is classified as carcinogenic hazard to humans.[12]

Magnetism

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Hematite shows only a very feeble response to a magnetic field. Unlike magnetite, it is not noticeably attracted to an ordinary magnet. Hematite is an antiferromagnetic material below the Morin transition at 250 K (−23 °C), and a canted antiferromagnet or weakly ferromagnetic above the Morin transition and below its Néel temperature at 948 K (675 °C), above which it is paramagnetic.

The magnetic structure of α-hematite was the subject of considerable discussion and debate during the 1950s, as it appeared to be ferromagnetic with a Curie temperature of approximately 1,000 K (730 °C), but with an extremely small magnetic moment (0.002 Bohr magnetons). Adding to the surprise was a transition with a decrease in temperature at around 260 K (−13 °C) to a phase with no net magnetic moment. It was shown that the system is essentially antiferromagnetic, but that the low symmetry of the cation sites allows spin–orbit coupling to cause canting of the moments when they are in the plane perpendicular to the c axis. The disappearance of the moment with a decrease in temperature at 260 K (−13 °C) is caused by a change in the anisotropy which causes the moments to align along the c axis. In this configuration, spin canting does not reduce the energy.[13][14] The magnetic properties of bulk hematite differ from their nanoscale counterparts. For example, the Morin transition temperature of hematite decreases with a decrease in the particle size. The suppression of this transition has been observed in hematite nanoparticles and is attributed to the presence of impurities, water molecules and defects in the crystals lattice. Hematite is part of a complex solid solution oxyhydroxide system having various contents of H2O (water), hydroxyl groups and vacancy substitutions that affect the mineral's magnetic and crystal chemical properties.[15] Two other end-members are referred to as protohematite and hydrohematite.

Enhanced magnetic coercivities for hematite have been achieved by dry-heating a two-line ferrihydrite precursor prepared from solution. Hematite exhibited temperature-dependent magnetic coercivity values ranging from 289 to 5,027 oersteds (23–400 kA/m). The origin of these high coercivity values has been interpreted as a consequence of the subparticle structure induced by the different particle and crystallite size growth rates at increasing annealing temperature. These differences in the growth rates are translated into a progressive development of a subparticle structure at the nanoscale (super small). At lower temperatures (350–600 °C), single particles crystallize. However, at higher temperatures (600–1000 °C), the growth of crystalline aggregates, and a subparticle structure is favored.[16]

Mine tailings

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Hematite is present in the waste tailings of iron mines. A recently developed process, magnetation, uses magnets to glean waste hematite from old mine tailings in Minnesota's vast Mesabi Range iron district.[17] Falu red is a pigment used in traditional Swedish house paints. Originally, it was made from tailings of the Falu mine.[18]

Mars

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Image mosaic from the Mars Exploration Rover Microscopic Imager shows hematite spherules partly embedded in rock at the Opportunity landing site. Image is around 5 cm (2 in) across.

The spectral signature of hematite was seen on the planet Mars by the infrared spectrometer on the NASA Mars Global Surveyor[19] and 2001 Mars Odyssey[20] spacecraft in orbit around Mars. The mineral was seen in abundance at two sites[21] on the planet, the Terra Meridiani site, near the Martian equator at 0° longitude, and the Aram Chaos site near the Valles Marineris.[22] Several other sites also showed hematite, such as Aureum Chaos.[23] Because terrestrial hematite is typically a mineral formed in aqueous environments or by aqueous alteration, this detection was scientifically interesting enough that the second of the two Mars Exploration Rovers was sent to a site in the Terra Meridiani region designated Meridiani Planum. In-situ investigations by the Opportunity rover showed a significant amount of hematite, much of it in the form of small "Martian spherules" that were informally named "blueberries" by the science team. Analysis indicates that these spherules are apparently concretions formed from a water solution. "Knowing just how the hematite on Mars was formed will help us characterize the past environment and determine whether that environment was favorable for life".[24]

Jewelry

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Hematite is often shaped into beads, tumbling stones, and other jewellery components.[25] Hematite was once used as mourning jewelry.[26][7] Certain types of hematite- or iron-oxide-rich clay, especially Armenian bole, have been used in gilding. Hematite is also used in art such as in the creation of intaglio engraved gems. Hematine is a synthetic material sold as magnetic hematite.[27]

Pigment

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Hematite has been sourced to make pigments since earlier origins of human pictorial depictions, such as on cave linings and other surfaces, and has been employed continually in artwork through the eras. In Roman times, the pigment obtained by finely grinding hematite was known as sil atticum. Other names for the mineral when used in painting include colcotar and caput mortuum. In Spanish, it is called almagre or almagra, from the Arabic al-maghrah, red earth, which passed into English and Portuguese. Other ancient names for the pigment include ochra hispanica, sil atticum antiquorum, and Spanish brown.[28] It forms the basis for red, purple, and brown iron-oxide pigments, as well as being an important component of ochre, sienna, and umber pigments.[29] The main producer of hematite for the pigment industry is India, followed distantly by Spain.

Industrial purposes

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As mentioned earlier, hematite is an important mineral for iron ore. The physical properties of hematite are also employed in the areas of medical equipment, shipping industries, and coal production. Having high density and capable as an effective barrier against X-ray passage, it often is incorporated into radiation shielding. As with other iron ores, it often is a component of ship ballasts because of its density and economy. In the coal industry, it can be formed into a high specific density solution, to help separate coal powder from impurities.[30]

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See also

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References

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  1. ^ Dunlop, David J.; Özdemir, Özden (2001). Rock Magnetism: Fundamentals and Frontiers. Cambridge: Cambridge University Press. p. 73. ISBN 9780521000987.
  2. ^ Warr, L.N. (2021). "IMA–CNMNC approved mineral symbols". Mineralogical Magazine. 85 (3): 291–320. Bibcode:2021MinM...85..291W. doi:10.1180/mgm.2021.43. S2CID 235729616.
  3. ^ Anthony, John W.; Bideaux, Richard A.; Bladh, Kenneth W.; Nichols, Monte C. (eds.). "Hematite" (PDF). Handbook of Mineralogy. Vol. III. Chantilly, VA: Mineralogical Society of America. ISBN 978-0962209727. Retrieved December 22, 2018.
  4. ^ "Hematite Mineral Data". WebMineral.com. Retrieved December 22, 2018.
  5. ^ "Hematite". Mindat.org. Retrieved December 22, 2018.
  6. ^ a b Cornell, Rochelle M.; Schwertmann, Udo (1996). The Iron Oxides. Germany: Wiley. pp. 4, 26. ISBN 9783527285761. LCCN 96031931. Retrieved December 22, 2018.
  7. ^ a b Morgenthau, Mengo L. (1923). Minerals and Cut Stones: Reference Book Containing Condensed and Simplified Descriptions from Standard Works on Mineralogy. p. 23.
  8. ^ a b "Ochre". Industrial Minerals. Minerals Zone. Archived from the original on November 15, 2016. Retrieved December 22, 2018.
  9. ^ "Researchers find earliest evidence for modern human behavior in South Africa" (Press release). AAAS. ASU News. October 17, 2007. Retrieved December 22, 2018.
  10. ^ Levato, Chiara (2016). "Iron Oxides Prehistoric Mines: A European Overview" (PDF). Anthropologica et Præhistorica. 126: 9–23. Retrieved December 22, 2018.
  11. ^ Benvenuti, M.; Dini, A.; D'Orazio, M.; Chiarantini, L.; Corretti, A.; Costagliola, P. (June 2013). "The tungsten and tin signature of iron ores from Elba Island (Italy)". Archaeometry. 55 (3): 479–506. doi:10.1111/j.1475-4754.2012.00692.x.
  12. ^ "List of Classifications".
  13. ^ Dzyaloshinsky, I. E. (1958). "A thermodynamic theory of "weak" ferromagnetism of antiferromagnetics". Journal of Physics and Chemistry of Solids. 4 (4): 241–255. Bibcode:1958JPCS....4..241D. doi:10.1016/0022-3697(58)90076-3.
  14. ^ Moriya, Tōru (1960). "Anisotropic Superexchange Interaction and Weak Ferromagnetism" (PDF). Physical Review. 120 (1): 91. Bibcode:1960PhRv..120...91M. doi:10.1103/PhysRev.120.91.
  15. ^ Dang, M.-Z.; Rancourt, D. G.; Dutrizac, J. E.; Lamarche, G.; Provencher, R. (1998). "Interplay of surface conditions, particle size, stoichiometry, cell parameters, and magnetism in synthetic hematite-like materials". Hyperfine Interactions. 117 (1–4): 271–319. Bibcode:1998HyInt.117..271D. doi:10.1023/A:1012655729417. S2CID 94031594.
  16. ^ Vallina, B.; Rodriguez-Blanco, J. D.; Brown, A. P.; Benning, L. G.; Blanco, J. A. (2014). "Enhanced magnetic coercivity of α-Fe2O3 obtained from carbonated 2-line ferrihydrite" (PDF). Journal of Nanoparticle Research. 16 (3): 2322. Bibcode:2014JNR....16.2322V. doi:10.1007/s11051-014-2322-5. S2CID 137598876.
  17. ^ Redman, Chris (May 20, 2009). "The next iron rush". Money.cnn.com. Retrieved December 22, 2018.
  18. ^ "Sveriges mest beprövade husfärg" [Sweden's most proven house color] (in Swedish). Retrieved December 22, 2018.
  19. ^ "Mars Global Surveyor TES Instrument Identification of Hematite on Mars" (Press release). NASA. May 27, 1998. Archived from the original on May 13, 2007. Retrieved December 22, 2018.
  20. ^ Christensen, Philip R. (2004). "Formation of the hematite-bearing unit in Meridiani Planum: Evidence for deposition in standing water". Journal of Geophysical Research. 109 (E8): E08003. Bibcode:2004JGRE..109.8003C. doi:10.1029/2003JE002233.
  21. ^ Bandfield, Joshua L. (2002). "Global mineral distributions on Mars" (PDF). Journal of Geophysical Research. 107 (E6): E65042. Bibcode:2002JGRE..107.5042B. doi:10.1029/2001JE001510.
  22. ^ Glotch, Timothy D.; Christensen, Philip R. (2005). "Geologic and mineralogic mapping of Aram Chaos: Evidence for a water-rich history". Journal of Geophysical Research. 110 (E9): E09006. Bibcode:2005JGRE..110.9006G. doi:10.1029/2004JE002389. S2CID 53489327.
  23. ^ Glotch, Timothy D.; Rogers, D.; Christensen, Philip R. (2005). "A Newly Discovered Hematite-Rich Unit in Aureum Chaos: Comparison of Hematite and Associated Units With Those in Aram Chaos" (PDF). Lunar and Planetary Science. 36: 2159. Bibcode:2005LPI....36.2159G.
  24. ^ "Hematite". NASA. Retrieved December 22, 2018.
  25. ^ "Hematite: A primary ore of iron and a pigment mineral". geology.com. Retrieved 2023-09-07.
  26. ^ Oldershaw, Cally (2003). Firefly Guide to Gems. Firefly Books. p. 53. ISBN 978-1-55297-814-6.
  27. ^ "Magnetic Hematite". Mindat.org. Retrieved December 22, 2018.
  28. ^ Calvo Rebollar, Miguel (2009). Minerales y Minas de España. Vol. 4. Óxidos e hidróxidos [Minerals and mines of Spain Vol 4. Oxides and Hidroxides] (in Spanish). Madrid, Spain: Escuela Técnica Superior de Ingenieros de Minas de Madrid. Fundación Gómez Pardo. ISBN 978-84-95063-99-1.
  29. ^ "Colors from the Earth: Violet Hematite". www.naturalpigments.com. Retrieved 2023-09-07.
  30. ^ "Hematite: A primary ore of iron and a pigment mineral". geology.com. Retrieved 2023-09-07.
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