The "Rainbow Shield," an opal pendant made with Australian gem opal
|Hydrated silica. SiO2·nH2O|
|Color||Colorless, white, yellow, red, orange, green, brown, black, blue|
|Crystal habit||Irregular veins, in masses, in nodules|
|Fracture||Conchoidal to uneven|
|Mohs scale hardness||5.5–6|
|Luster||Subvitreous to waxy|
|Diaphaneity||opaque, translucent, transparent|
|Specific gravity||2.15 (+.08, -.90)|
|Polish luster||Vitreous to resinous|
|Optical properties||Single refractive, often anomalous double refractive due to strain|
|Refractive index||1.450 (+.020, -.080) Mexican opal may read as low as 1.37, but typically reads 1.42–1.43|
|Ultraviolet fluorescence||black or white body color: inert to white to moderate light blue, green, or yellow in long and short wave, may also phosphoresce, common opal: inert to strong green or yellowish green in long and short wave, may phosphoresce; fire opal: inert to moderate greenish brown in long and short wave, may phosphoresce|
|Absorption spectra||green stones: 660nm, 470nm cutoff|
|Diagnostic features||darkening upon heating|
|Solubility||hot salt water, bases, methanol, humic acid, hydrofluoric acid|
Opal is a hydrated amorphous form of silica; its water content may range from 3 to 21% by weight, but is usually between 6 and 10%. Because of its amorphous character, it is classed as a mineraloid, unlike the other crystalline forms of silica, which are classed as minerals. It is deposited at a relatively low temperature and may occur in the fissures of almost any kind of rock, being most commonly found with limonite, sandstone, rhyolite, marl, and basalt.
Opal is the national gemstone of Australia. Australian opal has often been cited as accounting for 95-97% of the world's supply of precious opal, with the state of South Australia accounting for 80% of the world's supply. Recent data suggests that the world supply of precious opal may have changed. In 2012, Ethiopian opal production was estimated to be 14,000 metric tons by the United States Geological Survey. USGS data from the same period (2012), reveals that Australian opal production to be $41 million. Because of the units of measurement, it is not possible to directly compare Australian and Ethiopian opal production, but these data and others suggest that the traditional percentages given for Australian opal production may be overstated.
The internal structure of precious opal makes it diffract light; depending on the conditions in which it formed, it can take on many colors. Precious opal ranges from clear through white, gray, red, orange, yellow, green, blue, magenta, rose, pink, slate, olive, brown, and black. Of these hues, the reds against black are the most rare, whereas white and greens are the most common. It varies in optical density from opaque to semitransparent.
Common opal, called "potch" by miners, does not show the display of color exhibited in precious opal.
- 1 Precious opal
- 2 Common opal
- 3 Other varieties of opal
- 4 Sources of opal
- 5 Synthetic opal
- 6 Local atomic structure of opals
- 7 Naming
- 8 Historical superstitions
- 9 Famous opals
- 10 See also
- 11 References
- 12 External links
Precious opal shows a variable interplay of internal colors, and though it is a mineraloid, it has an internal structure. At microscopic scales, precious opal is composed of silica spheres some 150 to 300 nm in diameter in a hexagonal or cubic close-packed lattice. These ordered silica spheres produce the internal colors by causing the interference and diffraction of light passing through the microstructure of the opal. The regularity of the sizes and the packing of these spheres determines the quality of precious opal. Where the distance between the regularly packed planes of spheres is around half the wavelength of a component of visible light, the light of that wavelength may be subject to diffraction from the grating created by the stacked planes. The colors that are observed are determined by the spacing between the planes and the orientation of planes with respect to the incident light. The process can be described by Bragg's law of diffraction.
Visible light of diffracted wavelengths cannot pass through large thicknesses of the opal. This is the basis of the optical band gap in a photonic crystal, of which opal is the best-known natural example. In addition, microfractures may be filled with secondary silica and form thin lamellae inside the opal during solidification. The term opalescence is commonly and erroneously used to describe this unique and beautiful phenomenon, which is correctly termed play of color. Contrarily, opalescence is correctly applied to the milky, turbid appearance of common or potch opal. Potch does not show a play of color.
For gemstone use, most opal is cut and polished to form a cabochon. "Solid" opal refers to polished stones consisting wholly of precious opal. Opals too thin to produce a "solid" may be combined with other materials to form attractive gems. An opal doublet consists of a relatively thin layer of precious opal, backed by a layer of dark-colored material, most commonly ironstone, dark or black common opal (potch), onyx, or obsidian. The darker backing emphasizes the play of color, and results in a more attractive display than a lighter potch. An opal triplet is similar to a doublet, but has a third layer, a domed cap of clear quartz or plastic on the top. The cap takes a high polish and acts as a protective layer for the opal. The top layer also acts as a magnifier, to emphasize the play of color of the opal beneath, which is often of lower quality. Triplet opals therefore have a more artificial appearance, and are not classed as precious opal.
Combined with modern techniques of polishing, doublet opal produces a similar effect to black or boulder opal at a fraction of the price. Doublet opal also has the added benefit of having genuine opal as the top visible and touchable layer, unlike triplet opals.
Besides the gemstone varieties that show a play of color, the other kinds of common opal include the milk opal, milky bluish to greenish (which can sometimes be of gemstone quality); resin opal, which is honey-yellow with a resinous luster; wood opal, which is caused by the replacement of the organic material in wood with opal; menilite, which is brown or grey; hyalite, a colorless glass-clear opal sometimes called Muller's glass; geyserite, also called siliceous sinter, deposited around hot springs or geysers; and diatomite or diatomaceous earth, the accumulations of diatom shells or tests.
Other varieties of opal
Fire opal is a transparent to translucent opal, with warm body colors of yellow to orange to red. It does not usually show any play of color, although occasionally a stone will exhibit bright green flashes. The most famous source of fire opals is the state of Querétaro in Mexico; these opals are commonly called Mexican fire opals. Fire opals that do not show play of color are sometimes referred to as jelly opals. Mexican opals are sometimes cut in their ryholitic host material if it is hard enough to allow cutting and polishing. This type of Mexican opal is referred to as a Cantera opal. Also, a type of opal from Mexico, referred to as Mexican water opal, is a colorless opal which exhibits either a bluish or golden internal sheen.
Girasol opal is a term sometimes mistakenly and improperly used to refer to fire opals, as well as a type of transparent to semitransparent type milky quartz from Madagascar which displays an asterism, or star effect, when cut properly. However, the true girasol opal is a type of hyalite opal that exhibits a bluish glow or sheen that follows the light source around. It is not a play of color as seen in precious opal, but rather an effect from microscopic inclusions. It is also sometimes referred to as water opal, too, when it is from Mexico. The two most notable locations of this type of opal are Oregon and Mexico.
Peruvian opal (also called blue opal) is a semiopaque to opaque blue-green stone found in Peru, which is often cut to include the matrix in the more opaque stones. It does not display pleochroism. Blue opal also comes from Oregon in the Owhyee region, as well as from Nevada around Virgin Valley.
Sources of opal
Australia produces around 97% of the world's opal; 90% is called light opal or white and crystal opal. White makes up 60% of the opal production, but cannot be found in all of the opal fields. Crystal opal or pure hydrated silica makes up 30% of the opal produced, 8% is black and only 2% is boulder opal.
The town of Coober Pedy in South Australia is a major source of opal. The world's largest and most valuable gem opal "Olympic Australis" was found in August 1956 at the "Eight Mile" opal field in Coober Pedy. It weighs 17,000 carats (3450 g) and is 11 in (280 mm) long, with a height of 4.75 in (121 mm) and a width of 4.5 in (110 mm). The Mintabie Opal Field located about 250 km north west of Coober Pedy has also produced large quantities of crystal opal and the rarer black opal. Over the years, it has been sold overseas incorrectly as Coober Pedy opal. The black opal is said to be some of the best examples found in Australia. Andamooka in South Australia is also a major producer of matrix opal, crystal opal, and black opal'. Another Australian town, Lightning Ridge in New South Wales, is the main source of black opal, opal containing a predominantly dark background (dark-gray to blue-black displaying the play of color). Boulder opal consists of concretions and fracture fillings in a dark siliceous ironstone matrix. It is found sporadically in western Queensland, from Kynuna in the north, to Yowah and Koroit in the south. Its largest quantities are found around Jundah and Quilpie (known as the "home of the boulder opal") in South West Queensland. Australia also has opalised fossil remains, including dinosaur bones in New South Wales, and marine creatures in South Australia. The rarest type of Australian opal is "pipe" opal, closely related to boulder opal, which forms in sandstone with some iron oxide content, usually as fossilized tree roots.
Although it has been reported that Northern African opal was used to make tools as early as 4000 BC, the first published report of gem opal from Ethiopia appeared in the 1994, with the discovery of precious opal in the Menz Gishe District, North Shewa Province. The opal, found mostly in the form of nodules, was of volcanic origin and was found predominantly within weathered layers of rhyolite. This Shewa Province opal, was mostly dark brown in color, and had a tendency to crack. These qualities made it unpopular in the gem trade. In 2008, a new opal deposit was found near the town of Wegel Tena, in Ethiopia's Wollo Province. The Wollo Province opal was different than the previous Ethiopian opal finds in that it more closely resembled the sedimentary opals of Australia and Brazil, with a light background and often vivid play-of-color. Wollo Province opal, more commonly referred to as "Welo" or "Wello" opal has become the dominant Ethiopian opal in the gem trade.
Virgin Valley, Nevada
The Virgin Valley opal fields of Humboldt County in northern Nevada produce a wide variety of precious black, crystal, white, fire, and lemon opal. The black fire opal is the official gemstone of Nevada. Most of the precious opal is partial wood replacement. The precious opal is hosted and found within a subsurface horizon or zone of bentonite in-place which is considered a "lode" deposit. Opals which have weathered out of the in-place deposits are alluvial and considered placer deposits. Miocene-age opalised teeth, bones, fish, and a snake head have been found. Some of the opal has high water content and may desiccate and crack when dried. The largest producing mines of Virgin Valley have been the famous Rainbow Ridge, Royal Peacock, Bonanza, Opal Queen, and WRT Stonetree/Black Beauty Mines. The largest unpolished black opal in the Smithsonian Institution, known as the "Roebling opal", came out of the tunneled portion of the Rainbow Ridge Mine in 1917, and weighs 2,585 carats. The largest polished black opal in the Smithsonian Institution comes from the Royal Peacock opal mine in the Virgin Valley, weighing 160 carats, known as the "Black Peacock".
Other significant deposits of precious opal around the world can be found in the Czech Republic, Slovakia, Hungary, Turkey, Indonesia, Brazil (in Pedro II, Piauí), Honduras, Guatemala and Nicaragua.
Opals of all varieties have been synthesized experimentally and commercially. The discovery of the ordered sphere structure of precious opal led to its synthesis by Pierre Gilson in 1974. The resulting material is distinguishable from natural opal by its regularity; under magnification, the patches of color are seen to be arranged in a "lizard skin" or "chicken wire" pattern. Furthermore, synthetic opals do not fluoresce under ultraviolet light. Synthetics are also generally lower in density and are often highly porous.
Two notable producers of synthetic opal are Kyocera and Inamori of Japan. Most so-called synthetics, however, are more correctly termed "imitation opal", as they contain substances not found in natural opal (e.g., plastic stabilizers). The imitation opals seen in vintage jewelry are often foiled glass, glass-based "Slocum stone", or later plastic materials.
Other research in macroporous structures have yielded highly ordered materials that have similar optical properties to opals and have been used in cosmetics.
Local atomic structure of opals
The lattice of spheres of opal that cause the interference with light are several hundred times larger than the fundamental structure of crystalline silica. As a mineraloid, no unit cell describes the structure of opal. Nevertheless, opals can be roughly divided into those that show no signs of crystalline order (amorphous opal) and those that show signs of the beginning of crystalline order, commonly termed cryptocrystalline or microcrystalline opal. Dehydration experiments and infrared spectroscopy have shown that most of the H2O in the formula of SiO2·nH2O of opals is present in the familiar form of clusters of molecular water. Isolated water molecules, and silanols, structures such as SiOH, generally form a lesser proportion of the total and can reside near the surface or in defects inside the opal.
The structure of low-pressure polymorphs of anhydrous silica consist of frameworks of fully corner bonded tetrahedra of SiO4. The higher temperature polymorphs of silica cristobalite and tridymite are frequently the first to crystallize from amorphous anhydrous silica, and the local structures of microcrystalline opals also appear to be closer to that of cristobalite and tridymite than to quartz. The structures of tridymite and cristobalite are closely related and can be described as hexagonal and cubic close-packed layers. It is therefore possible to have intermediate structures in which the layers are not regularly stacked.
Opal-CT has been interpreted as consisting of clusters of stacking of cristobalite and tridymite over very short length scales. The spheres of opal in opal-CT are themselves made up of tiny microcrystalline blades of cristobalite and tridymite. Opal-CT has occasionally been further subdivided in the literature. Water content may be as high as 10 wt%. Lussatite is a synonym. Opal-C, also called lussatine, is interpreted as consisting of localized order of -cristobalite with a lot of stacking disorder. Typical water content is about 1.5wt%.
Two broad categories of noncrystalline opals, sometimes just referred to as "opal-A", have been proposed. The first of these is opal-AG consisting of aggregated spheres of silica, with water filling the space in between. Precious opal and potch opal are generally varieties of this, the difference being in the regularity of the sizes of the spheres and their packing. The second "opal-A" is opal-AN or water-containing amorphous silica-glass. Hyalite is another name for this.
Noncrystalline silica in siliceous sediments is reported to gradually transform to opal-CT and then opal-C as a result of diagenesis, due to the increasing overburden pressure in sedimentary rocks, as some of the stacking disorder is removed.
References to the gem are made by Pliny the Elder. It is suggested to have been adapted from Ops, the wife of Saturn and goddess of fertility. The portion of Saturnalia devoted to Ops was "Opalia", similar to opalus.
Another common claim that the term is adapted from the Greek word, opallios. This word has two meanings, one is related to "seeing" and forms the basis of the English words like "opaque"; the other is "other" as in "alias" and "alter". It is claimed that opalus combined these uses, meaning "to see a change in color". However, historians have noted the first appearances of opallios do not occur until after the Romans had taken over the Greek states in 180 BC, and they had previously used the term paederos.
However, the argument for the Sanskrit origin is strong. The term first appears in Roman references around 250 BC, at a time when the opal was valued above all other gems. The opals were supplied by traders from the Bosporus, who claimed the gems were being supplied from India. Before, this the stone was referred to by a variety of names, but these fell from use after 250 BC.
In the Middle Ages, opal was considered a stone that could provide great luck because it was believed to possess all the virtues of each gemstone whose color was represented in the color spectrum of the opal. It was also said to confer the power of invisibility if wrapped in a fresh bay leaf and held in the hand. Following the publication of Sir Walter Scott's Anne of Geierstein in 1829, opal acquired a less auspicious reputation. In Scott's novel, the Baroness of Arnheim wears an opal talisman with supernatural powers. When a drop of holy water falls on the talisman, the opal turns into a colorless stone and the Baroness dies soon thereafter. Due to the popularity of Scott's novel, people began to associate opals with bad luck and death. Within a year of the publishing of Scott's novel in April 1829, the sale of opals in Europe dropped by 50%, and remained low for the next 20 years or so.
Even as recently as the beginning of the 20th century, it was believed that when a Russian saw an opal among other goods offered for sale, he or she should not buy anything more, as the opal was believed to embody the evil eye.
- The Olympic Australis, the world's largest and most valuable gem opal
- The Andamooka Opal, presented to Queen Elizabeth II, also known as the Queen's Opal
- The Addyman Plesiosaur from Andamooka, "the finest known opalised skeleton on Earth"
- The Burning of Troy, the now-lost opal presented to Joséphine de Beauharnais by Napoleon I of France and the first named opal
- The Flame Queen Opal
- The Halley's Comet Opal, the world's largest uncut black opal
- Although the clock faces above the information stand in Grand Central Terminal Manhattan, New York, are often said to be opal, they are in fact opalescent glass
- The Roebling Opal, Smithsonian Institution
- The Galaxy Opal, listed as the "World's Largest Polished Opal" in the 1992 Guinness Book of Records
|Wikisource has original text related to this article:|
- Gemological Institute of America, GIA Gem Reference Guide 1995, ISBN 0-87311-019-6
- "Opal". Webmineral. Retrieved 2011-10-08.
- "Opal". Mindat.org. Retrieved 2011-10-08.
- Gemstone, It's an Honour (Australian Government site)
- "Opal - New World Encyclopedia".
- "Rapaport Magazine - A Designer Stone".
- "Opal Mining in Australia | All About Mining".
- Government of South Australia >Insignia and Emblems > Opal – South Australia's Gemstone Accessed 11 July 2012.
- Yager, Thomas R. (2013-12-01), "The Mineral Industry of Ethiopia", United States Geological Survey, 2012 Minerals Yearbook, pp. 17.1–17.5
- Tse, Pui-Kwan (2013-12-01), "The Mineral Industry of Australia", United States Geological Survey, 2012 Minerals Yearbook, pp. 3.1–3.27, retrieved 2014-09-20
- "Rapaport Magazine - Ethiopian Opal".
- "Australian Gemstones".
- Downing, Paul B.,Ph.D "Opal Identification and Value", 1992, pp. 55-61.
- Klein, Cornelis, and Hurlbut, Cornelius S.; 1985, Manual of Mineralogy, 20th ed., ISBN 0-471-80580-7
- Gribble, C. D. (1988). "Tektosilicates (framework silicates)". Rutley's Elements of Mineralogy (27th ed. ed.). London: Unwin Hyman. p. 431. ISBN 0-04-549011-2.
- James Swisher, Gemologist, and Edna B. Anthony, Gemologist, Let's Talk Gemstones: Opal
- Yowah Nut: Yowah Nut mineral information and data. Mindat.org (2011-02-20). Retrieved on 2011-03-08.
- Cram, Len (2006). A history of South Australian opal, 1840-2005. Lightning Ridge, NSW. ISBN 978-0975721407.
- Queensland opal[dead link]
- Quilpie Shire Council "Simply Unique" 2010. page 8
- South Australian Museum > Explore > Museum Galleries > Opal Fossils Accessed 3 March 2014.
- Barot, N (1994). "New precious opal deposit found in Ethiopia". ICA Gazette (New York: The International Colored Gemstone Association).
- Johnson, Mary L.; Kammerling, Robert C.; DeGhionno, Dino G.; Koivula, John I. (Summer 1996). "Opal from Shewa Province, Ethiopia". Gems & Gemology 32 (2): 112–120.
- Rondeau, Benjamin (Summer 2010). "Play-of-color from Wegel Tena, Wollo Province, Ethiopia". Gems & Gemology (San Diego, CA USA: Gemological Institute of America).
- Gashaw, Yidneka (April 8, 2012). "Opal Trade Transforms North Wollo". Addis Fortune (Addis Ababa, Ethiopia).
- Virgin Valley District, Humboldt Co., Nevada, mindat.org
- Rainbow Ridge Mine, mindat.org
- Royal Peacock Group Mines, Virgin Valley District, Humboldt Co., Nevada, mindat.org
- Bonanza Opal Workings (Virgin Opal), Virgin Valley District, Humboldt Co., Nevada, mindat.org
- Opal Queen group, Virgin Valley District, Humboldt Co., Nevada, mindat.org
- Stonetree Opal Mine, WRT Stonetree group, Virgin Valley District, Humboldt Co., Nevada, mindat.org
- Roebling Opal, National Museum of Natural History
- Lapidary Journal, March 1971, p. 1522, 1542; cover
- "Boi Morto Mine, Pedro II, Piauí, Brazil". Mindat.org. Retrieved 2011-10-08.
- "NASA probe finds opals in Martian crevices". Retrieved 2008-10-29.
- "Macroporous Structures, Metal Oxides, Highly_Ordered – Office for Technology Commercialization, Express_license, University_of_Minnesota, Technology_Marketing_Site". License.umn.edu. 2010-06-25. Retrieved 2011-10-08.
- Graetsch, H., "Structural Characteristics of opaline and microcrystalline silica minerals", "Silica, physical behavior, geochemistry and materials applications". Reviews in Mineralogy, Vol. 29, 1994. Editors PJ Heaney, Connecticut Prewitt, GV Gibbs, Mineralogical Society of America
- "(Cady et al., 1996)" (PDF). Retrieved 2011-10-08.
- Allan Eckert, The World of Opals, John Wiley and Sons, 1997, pp. 56–57
- Fernie, William Thomas (907). Precious Stones for Curative Wear. Bristol, John Wright & Co. pp. 248–249.
- Dunwich, Gerina (1996). Wicca Candle Magick. pp. 84–85.
- Eckert, Allan W. "A Chronological History and Mythology of Opals." In: The World of Opals. New York: John Wiley & Sons, 1997. See pp. 53-118.
- South Australian Museum > Explore > Museum Galleries > Opal Fossils Accessed 3 March 2014.
- Eckert, Allan W. (1997). The World of Opals. Chichester: John Wiley & Sons. pp. 67, 126. ISBN 0-471-13397-3.
- "The Dynamic Earth @ National Museum of Natural History". Mnh.si.edu. Retrieved 2011-10-08.
- "The Guinness book of records, 1993" October 1992, ISBN 0-85112-978-1, p.22
|Wikimedia Commons has media related to Opal.|
|Look up opal in Wiktionary, the free dictionary.|
- Farlang opal Hist. References Localities, anecdotes by Theophrastus, Isaac Newton, Georg Agricola etc.
- ICA's Opal Page: International Colored Stone Association
- South Australian Museum > The Opal Fossils of South Australia Accessed 2 December 2011.