Selenite (mineral)

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Selenite
Gypse-selenite 3.jpeg
General
Category Sulfate mineral
Formula
(repeating unit)		CaSO4·2H2O
Crystal system Monoclinic (2/m) Space group: A2/a
Identification
Formula mass 172.17
ColorBrown green, brownish yellow, greenish, gray green, gray white
Crystal habit Earthy – dull, clay-like texture with no visible crystalline affinities, (e.g. howlite)
Cleavage [010] Perfect, [100] Distinct, [011] Distinct
Fracture Fibrous – thin, elongated fractures produced by crystal forms or intersecting cleavages (e.g. asbestos).
Mohs scale hardness2
Luster Pearly
Streak White
Specific gravity 2.9
Optical propertiesBiaxial (+) 2V=58
Refractive index nα = 1.519–1.521,
nβ = 1.522–1.523,
nγ = 1.529–1.53
Birefringence δ = 0.0090–0.0100
Other characteristicsNon-radioactive, non-magnetic, fluorescent
References [1]

Selenite, satin spar, desert rose , and gypsum flower are crystal habit varieties of the mineral gypsum.

Contents

All varieties of gypsum, including selenite and alabaster, are composed of calcium sulfate dihydrate (meaning that it has two molecules of water), with the chemical formula CaSO4·2H2O. Selenite contains no significant selenium   The similar names both derive from Greek selḗnē ( σελήνη 'Moon').

Some of the largest crystals ever found are of selenite, the largest specimen found in the Naica Mine's Cave of the Crystals being 12 metres long and weighing 55 tons.

History and etymology

"Selenite" is mostly synonymous with gypsum, [2] but from the 15th century, it has named the transparent variety that occurs in crystals or crystalline masses. The name derives through Middle English selenite from Latin selenites , ultimately from Greek selēnítēs líthos ( σεληνίτης λίθος , lit.'moon stone'). It got this name because people historically believed the mineral waxed and waned with the cycles of the Moon. [3]

Distinguishing characteristics

The main distinguishing characteristics of crystalline gypsum are its softness (hardness 2 on Mohs scale, soft enough to scratch with a fingernail) and its three unequal cleavages. [4] [5] Other distinguishing characteristics include its crystal habits, pearly lustre, easy fusibility with loss of water, and solubility in hot dilute hydrochloric acid. [6]

Varieties

Though sometimes grouped together as "selenite", the four crystalline varieties have differences. General identifying descriptions of the related crystalline varieties are:

Selenite

Satin spar

Desert rose

Gypsum flower

Use and history

Satin spar is sometimes cut into cabochons to best display its chatoyance. [15]

Crystal habit and properties

Columnar crystal habit Gfp-Gypsum-v-selenite.jpg
Columnar crystal habit
"Gypsum flower" speleothem, Mammoth Cave Kentucky. Orange color is iron oxide from groundwater. Gypsum speleothem (Cleaveland Avenue, Mammoth Cave.jpg
"Gypsum flower" speleothem, Mammoth Cave Kentucky. Orange color is iron oxide from groundwater.

Crystal habit refers to the shapes that crystals exhibit. [16] Selenite crystals show a variety of habits, but the most common are tabular, prismatic, or acicular (columnar) crystals, [9] often with no imperfections or inclusions. [15] Twinned crystals are common, and often take the form of "swallow tail" twins. [9]

Selenite crystals sometimes form in thin tabular or mica-like sheets and have been used as window panes [17] [18] as at Santa Sabina in Rome. [19]

Selenite crystals sometimes will also exhibit bladed rosette habit (usually transparent and like desert roses) often with accompanying transparent, columnar crystals. Selenite crystals can be found both attached to a matrix or base rock, but can commonly be found as entire free-floating crystals, often in clay beds (and as can desert roses). [15]

Satin spar is almost always prismatic [ citation needed ] and fibrous in a parallel crystal habit. Satin spar often occurs in seams, [9] some of them quite long, and is often attached to a matrix or base rock.[ citation needed ]

Desert roses are most often bladed, exhibiting the familiar shape of a rose, and almost always have an exterior druse. [15] Desert roses form in wet sand, unattached to a matrix or base rock. [20]

Gypsum flowers are most often acicular, scaly, stellate, and lenticular. Gypsum flowers most often exhibit simple twinning (known as contact twins); where parallel, long, needle-like crystals, sometimes having severe curves and bends, will frequently form “ram’s horns”, "fishtail", "arrow/spear-head", and "swallowtail" twins. Selenite crystals can also exhibit “arrow/spear-head” as well as “duck-bill” twins. Both selenite crystals and gypsum flowers sometimes form quite densely in acicular mats or nets; and can be quite brittle and fragile. Gypsum flowers are usually attached to a matrix (can be gypsum) or base rock. [21] [22]

Color

Azurite-gypsum "Buda Rock", Ray Mine Arizona. A core of glassy and colorless gypsum crystals up to 1 cm in length with a druse of royal blue azurite, to 0.5 cm in length on the smaller gypsum crystals and included within the larger ones. Azurite-Gypsum-uri-14c.jpg
Azurite-gypsum "Buda Rock", Ray Mine Arizona. A core of glassy and colorless gypsum crystals up to 1 cm in length with a druse of royal blue azurite, to 0.5 cm in length on the smaller gypsum crystals and included within the larger ones.

Gypsum crystals are colorless (most often selenite), white (or pearly – most often satin spar), or gray, but may be tinted brown, yellow, red, or blue by the presence of impurities, such as iron oxides or clay minerals. [23] [9]

Transparency

Gypsum crystals can be transparent (most often selenite), translucent (most often satin spar but also selenite and gypsum flowers), [23] and opaque (most often the rosettes and flowers). Opacity can be caused by impurities, inclusions, druse, and crust, and can occur in all four crystalline varieties.

Luster

Selenite typically shows vitreous luster, but may show pearly luster on cleavage surfaces. Satin spar shows characteristic silky luster. [9] Luster is not often exhibited in the rosettes, due to their exterior druse; nevertheless, the rosettes often show glassy to pearly luster on edges. Gypsum flowers usually exhibit more luster than desert roses.[ citation needed ]

Other optical properties

Fibrous satin spar exhibits chatoyancy (cat's eye effect). [10]

When cut across the fibers and polished on the ends, satin spar exhibits an optical illusion when placed on a printed or pictured surface: print and pictures appear to be on the surface of the sample. It is often called and sold as the “television stone” (as is ulexite). [24]

Some selenite and satin spar specimens exhibit fluorescence or phosphorescence. [15]

Tenacity

All four crystalline varieties are slightly flexible, though will break if bent significantly. They are not elastic, meaning they can be bent, but will not bend back on their own. [9]

All four crystalline varieties are sectile in that they can be easily cut, will peel (particularly selenite crystals that exhibit mica-like properties), and like all gypsum varieties, can be scratched by a fingernail (hardness: 2 on Mohs Scale). [9] [7] The rosettes are not quite as soft due to their exterior druse; nevertheless, they too can be scratched.[ citation needed ]

Selenite crystals that exhibit in either reticular or acicular habits, satin spar, in general (as fibrous crystals are thin and narrow), desert roses that are thinly bladed, and gypsum flowers, particularly acicular gypsum flowers, can be quite brittle and easily broken.[ citation needed ]

Size

All four crystalline varieties can range in size from minute to giant selenite crystals measuring 11 meters long such as those found in the caves of the Naica Mine of Chihuahua, Mexico. The crystals thrived in the cave's extremely rare and stable natural environment. Temperatures stayed at 58 °C, and the cave was filled with mineral-rich water that drove the crystals' growth. The largest of those crystals weighs 55 tons, is 11 meters (36 ft) long, and is over 500,000 years old. [25]

Occurrence

Gypsum occurs on every continent and is the most common of all the sulfate minerals.

Gypsum is formed as an evaporative mineral, frequently found in alkaline lake muds, clay beds, evaporated seas, salt flats, salt springs, and caves. It is frequently found in conjunction with other minerals such as, copper ores, sulfur and sulfides, silver, iron ores, coal, calcite, dolomite, limestone, and opal. Gypsum has been dated to almost every geologic age since the Silurian Period 443.7 ± 1.5 Ma. [26]

In dry, desert conditions and arid areas, sand may become trapped both on the inside and the outside of gypsum crystals as they form. Interior inclusion of sand can take on shapes such as an interior hourglass shape common to selenite crystals of the ancient Great Salt Plains Lake bed, Oklahoma, US. [27] Exterior inclusion (druse) occurs as embedded sand grains on the surface such as, commonly seen in the familiar desert rose.

When gypsum dehydrates severely, anhydrite is formed. If water is reintroduced, gypsum can and will reform – including as the four crystalline varieties. An example of gypsum crystals reforming in modern times is found at Philips Copper Mine (closed and abandoned), Putnam County, New York, US where selenite micro crystal coatings are commonly found on numerous surfaces (rock and otherwise) in the cave and in the dump. [28]

Images

See also

Related Research Articles

<span class="mw-page-title-main">Crystal</span> Solid material with highly ordered microscopic structure

A crystal or crystalline solid is a solid material whose constituents are arranged in a highly ordered microscopic structure, forming a crystal lattice that extends in all directions. In addition, macroscopic single crystals are usually identifiable by their geometrical shape, consisting of flat faces with specific, characteristic orientations. The scientific study of crystals and crystal formation is known as crystallography. The process of crystal formation via mechanisms of crystal growth is called crystallization or solidification.

<span class="mw-page-title-main">Gypsum</span> Soft calcium sulfate mineral

Gypsum is a soft sulfate mineral composed of calcium sulfate dihydrate, with the chemical formula CaSO4·2H2O. It is widely mined and is used as a fertilizer and as the main constituent in many forms of plaster, drywall and blackboard or sidewalk chalk. Gypsum also crystallizes as translucent crystals of selenite. It forms as an evaporite mineral and as a hydration product of anhydrite. The Mohs scale of mineral hardness defines gypsum as hardness value 2 based on scratch hardness comparison.

<span class="mw-page-title-main">Quartz</span> Mineral made of silicon and oxygen

Quartz is a hard, crystalline mineral composed of silica (silicon dioxide). The atoms are linked in a continuous framework of SiO4 silicon–oxygen tetrahedra, with each oxygen being shared between two tetrahedra, giving an overall chemical formula of SiO2. Quartz is, therefore, classified structurally as a framework silicate mineral and compositionally as an oxide mineral. Quartz is the second most abundant mineral in Earth's continental crust, behind feldspar.

<span class="mw-page-title-main">Calcite</span> Calcium carbonate mineral

Calcite is a carbonate mineral and the most stable polymorph of calcium carbonate (CaCO3). It is a very common mineral, particularly as a component of limestone. Calcite defines hardness 3 on the Mohs scale of mineral hardness, based on scratch hardness comparison. Large calcite crystals are used in optical equipment, and limestone composed mostly of calcite has numerous uses.

Lustre or luster is the way light interacts with the surface of a crystal, rock, or mineral. The word traces its origins back to the Latin lux, meaning "light", and generally implies radiance, gloss, or brilliance.

<span class="mw-page-title-main">Ulexite</span> Mineral (hydrated sodium calcium borate hydroxide)

Ulexite sometimes called TV rock or TV stone due to its unusual optical properties, is a hydrous borate hydroxide of sodium and calcium with the chemical formula NaCaB5O6(OH)6·5H2O. The mineral occurs as silky white rounded crystalline masses or in parallel fibers. Ulexite was named for the German chemist Georg Ludwig Ulex (1811–1883), who first discovered it.

<span class="mw-page-title-main">Aragonite</span> Calcium carbonate mineral

Aragonite is a carbonate mineral and one of the three most common naturally occurring crystal forms of calcium carbonate, the others being calcite and vaterite. It is formed by biological and physical processes, including precipitation from marine and freshwater environments.

<span class="mw-page-title-main">Vug</span> Small to medium-sized cavity inside rock

A vug, vugh, or vugg is a small- to medium-sized cavity inside rock. It may be formed through a variety of processes. Most commonly, cracks and fissures opened by tectonic activity are partially filled by quartz, calcite, and other secondary minerals. Open spaces within breccias formed by an ancient collapse are another important source of vugs.

<span class="mw-page-title-main">Pyrophyllite</span> Aluminium silicate hydroxide phyllosilicate mineral

Pyrophyllite is a phyllosilicate mineral composed of aluminium silicate hydroxide: Al2Si4O10(OH)2. It occurs in two forms (habits): crystalline folia and compact masses; distinct crystals are not known.

<span class="mw-page-title-main">Desert rose (crystal)</span> Rose-like formation of crystal clusters of gypsum or baryte

A desert rose is an intricate rose-like formation of crystal clusters of gypsum or baryte, which include abundant sand grains. The "petals" are crystals flattened on the c axis, fanning open in radiating clusters.

<span class="mw-page-title-main">Natrolite</span> Zeolite mineral

Natrolite is a tectosilicate mineral species belonging to the zeolite group. It is a hydrated sodium and aluminium silicate with the formula Na2Al2Si3O10·2H2O. The type locality is Hohentwiel, Hegau, Germany.

<span class="mw-page-title-main">Olivenite</span> Copper arsenate mineral

Olivenite is a copper arsenate mineral, formula Cu2AsO4OH. It crystallizes in the monoclinic system (pseudo-orthorhombic), and is sometimes found in small brilliant crystals of simple prismatic habit terminated by domal faces. More commonly, it occurs as globular aggregates of acicular crystals, these fibrous forms often having a velvety luster; sometimes it is lamellar in structure, or soft and earthy.

<span class="mw-page-title-main">Botryoidal</span> Mineral shape resembling a small bunch of grapes

A botryoidal texture or mineral habit, is one in which the mineral has an external form composed of many rounded segments, named for the Ancient Greek βότρυς (bótrus), meaning "a bunch of grapes". This is a common form for many minerals, particularly hematite and malachite, which are known for frequently forming botryoidal masses. It is also a common form of goethite, smithsonite, fluorite, and chrysocolla.

<span class="mw-page-title-main">Todorokite</span> Hydrous manganese oxide mineral

Todorokite is a complex hydrous manganese oxide mineral with generic chemical formula (Na,Ca,K,Ba,Sr)
1-x(Mn,Mg,Al)
6O
12·3-4H
2O. It was named in 1934 for the type locality, the Todoroki mine, Hokkaido, Japan. It belongs to the prismatic class 2/m of the monoclinic crystal system, but the angle β between the a and c axes is close to 90°, making it seem orthorhombic. It is a brown to black mineral which occurs in massive or tuberose forms. It is quite soft with a Mohs hardness of 1.5, and a specific gravity of 3.49 – 3.82. It is a component of deep ocean basin manganese nodules.

<span class="mw-page-title-main">Anthodite</span> Speleothems composed of long needle-like crystals situated in clusters

Anthodites (Greek ἄνθος ánthos, "flower", -ode, adjectival combining form, -ite adjectival suffix) are speleothems (cave formations) composed of long needle-like crystals situated in clusters which radiate outward from a common base. The "needles" may be quill-like or feathery. Most anthodites are made of the mineral aragonite (a variety of calcium carbonate, CaCO3), although some are composed of gypsum (CaSO4·2H2O).

<span class="mw-page-title-main">Spar (mineralogy)</span> Crystal that has readily discernible faces

Spar is an old mining or mineralogy term used to refer to crystals that have readily discernible faces. A spar will easily break or cleave into rhomboidal, cubical, or laminated fragments with smooth shiny surfaces.

<span class="mw-page-title-main">Cave of the Crystals</span> Mexican cave renowned for its giant crystals

Cave of the Crystals or Giant Crystal Cave is a cave connected to the Naica Mine at a depth of 300 metres (980 ft), in Naica, Chihuahua, Mexico. It takes the form of a chamber within the limestone host rock of the mine, and is about 109 metres (358 ft) long with a volume of 5,000 to 6,000 cubic metres.

<span class="mw-page-title-main">Acicular (crystal habit)</span> Crystal habit

Acicular, in mineralogy, refers to a crystal habit composed of slender, needle-like crystals. Crystals with this habit tend to be fragile. Complete, undamaged acicular specimens are uncommon.

Chukanovite is an iron(II) hydroxide-carbonate mineral with the ideal chemical formula Fe+22(CO3)(OH)2. It is a member of the rosasite mineral group and crystalizes in the monoclinic crystal system. Upon initial crystallization, it is typically pale green to colorless, but it takes on a brownish green hue after being altered at the surface. As a weathering product of meteoritic iron, chukanovite is a relatively uncommon mineral on Earth, having only been discovered in the year 2000. However, it is commonly formed artificially as a corrosion byproduct through the manufacturing of sand-deposited carbon steel.

<span class="mw-page-title-main">Satin spar</span> Index of articles associated with the same name

Satin spar, less commonly atlas spar — is a trivial, partly obsolete name for fibrous varieties of two minerals, gypsum and calcite, possessing a characteristic silky (satin) luster. Despite their very low hardness, both atlas (satin) spars are widely used as ornamental stones.

References

  1. "Gypsum Mineral Data". Weinrich Minerals, Inc. Retrieved 20 October 2013.
  2. Selenite on Mindat.org
  3. Etymology of selenite from the New Collegiate Dictionary.
  4. Klein, Cornelis; Hurlbut, Cornelius S. Jr. (1993). Manual of mineralogy : (after James D. Dana) (21st ed.). New York: Wiley. p. 428. ISBN   047157452X.
  5. Nesse, William D. (2000). Introduction to mineralogy. New York: Oxford University Press. p. 343. ISBN   9780195106916.
  6. Sinkankas, John (1964). Mineralogy for amateurs. Princeton, N.J.: Van Nostrand. p. 398. ISBN   0442276249.
  7. 1 2 Klein & Hurlbut 1993, p. 427.
  8. 20120269950,Hooper, Mark&Rodriguez, Jose M.,"Chemical changes associated with selenite",issued 2012-10-25
  9. 1 2 3 4 5 6 7 8 Nesse 2000, p. 343.
  10. 1 2 Sinkankas 1964, p. 400.
  11. Sinkankas 1964, p. 361.
  12. Desert rose on Mindat.org
  13. Sinkankas 1964, p. 390.
  14. White, William B. (13 March 2020). "Cave". Encyclopedia Britannica. Retrieved 11 March 2021.
  15. 1 2 3 4 5 "Gypsum, selenite: The mineral gypsum information and pictures".
  16. "Habit". The mineral identification key. Mineralogical Society of America. Retrieved 20 October 2013.
  17. "Kristallgrotte – photograph of selenite crystals in the (below)". Archived from the original on 2007-02-17.
  18. Jochen Duckeck (27 December 2011). "Marienglashöhle". showcaves.com. Retrieved 20 October 2013. Show Mine, Germany – selenite was commonly used in Germany during medieval times for window panes and, in particular, for coverings of pictures of the Madonna. In Germany, this form of selenite was usually referred to as Marienglas or Mary’s Glass.
  19. Viar, Lucas (5 December 2019). "The Basilica of Santa Sabina: Origins and Transformations". Liturgical Arts Journal. Retrieved 12 March 2021.
  20. Hope, Sigmund Mongstad; Kundu, Sumanta; Roy, Chandreyee; Manna, Subhrangshu S.; Hansen, Alex (8 September 2015). "Network topology of the desert rose". Frontiers in Physics. 3: 72. Bibcode:2015FrP.....3...72H. doi: 10.3389/fphy.2015.00072 . hdl: 11250/2387742 .
  21. Huff, Lyman C. (August 1940). "Artificial Helictites and Gypsum Flowers". The Journal of Geology. 48 (6): 641–659. Bibcode:1940JG.....48..641H. doi:10.1086/624919. S2CID   129904216.
  22. Ghergari, L.; Onac, Bogdan (1995). "The crystallogenesis of gypsum flowers". Cave and Karst Science. 22: 119–122. Retrieved 12 March 2021.
  23. 1 2 Sinkankas 1964, p. 398.
  24. Jeffrey Shallit; Peter Russell. "Ulexite or Satin Spar Gypsum? The Scoop on "Television Stone"". University of Waterloo, Canada. discussion whether ulexite or satin spar is the “real” television stone. When the optical illusion that some satin spar can exhibit was “discovered”, satin spar was “marketed” as ulexite, rather than as a gypsum variety. Ulexite is a different mineral.
  25. Alleyne, Richard (2008-10-27). "World's largest crystal discovered in Mexican cave". London: The Telegraph. Retrieved 2009-06-06.
  26. Surface Mining – Industrial Minerals – Gypsum and Anhydrite, Richard H Olson, Edwin H Bentzen, III, and Gordon C Presley, Editors, SME – Society for Mining, Metallurgy, and Exploration, US Archived 2007-06-25 at the Wayback Machine
  27. Salt Plains National Wildlife Refuge, Oklahoma, US – website showing photographs of sand-colored hour-glass formations in clear selenite columnar crystals
  28. Anthony’s Nose, New York: A Review of Three Mineral Localities, by John Betts, Fine Minerals – Philips Copper Mine and the re-formation of selenite crystals
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