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Chrysoberyl

August 21, 2023

The mineral or gemstone chrysoberyl is an aluminate of beryllium with the formula BeAl2O4.[5][6] The name chrysoberyl is derived from the Greek words χρυσός chrysos and βήρυλλος beryllos, meaning "a gold-white spar". Despite the similarity of their names, chrysoberyl and beryl are two completely different gemstones, although they both contain beryllium. Chrysoberyl is the third-hardest frequently encountered natural gemstone and lies at 8.5 on the Mohs scale of mineral hardness, between corundum (9) and topaz (8).[7]

Chrysoberyl
Cyclic trilling of chrysoberyl
General
CategoryOxide minerals
Formula
(repeating unit)		BeAl2O4
IMA symbolCbrl[1]
Strunz classification4.BA.05
Crystal systemOrthorhombic
Crystal classDipyramidal (mmm)
H-M symbol: (2/m 2/m 2/m)
Space groupPbnm
Unit cella = 5.481 Å,
b = 9.415 Å,
c = 4.428 Å; Z = 4
Identification
ColorVarious shades of green, emerald-green yellow, blue, brownish to greenish black, may be raspberry-red under incandescent light when chromian; colorless, pale shades of yellow, green, or red in transmitted light
Crystal habitCrystals tabular or short prismatic, prominently striated
TwinningContact and penetration twins common, often repeated forming rosette structures
CleavageDistinct on {110}, imperfect on {010}, poor on {001}
FractureConchoidal to uneven
TenacityBrittle
Mohs scale hardness8.5
LusterVitreous
StreakWhite
Specific gravity3.5–3.84
Optical propertiesBiaxial (+)
Refractive indexnα=1.745 nβ=1.748 nγ=1.754
PleochroismX = red; Y = yellow-orange; Z = emerald-green
2V angleMeasured: 70°
References[2][3][4][5]
Major varieties
AlexandriteColor change; green to red
CymophaneChatoyant
Main chrysoberyl producing countries

An interesting feature of its crystals are the cyclic twins called trillings. These twinned crystals have a hexagonal appearance, but are the result of a triplet of twins with each "twin" oriented at 120° to its neighbors and taking up 120° of the cyclic trilling. If only two of the three possible twin orientations are present, a "V"-shaped twin results.

Ordinary chrysoberyl is yellowish-green and transparent to translucent. When the mineral exhibits good pale green to yellow color and is transparent, then it is used as a gemstone. The three main varieties of chrysoberyl are: ordinary yellow-to-green chrysoberyl, cat's eye or cymophane, and alexandrite. Yellow-green chrysoberyl was referred to as "chrysolite" during the Victorian and Edwardian eras, which caused confusion since that name has also been used for the mineral olivine ("peridot" as a gemstone); that name is no longer used in the gemological nomenclature.

Alexandrite, a strongly pleochroic (trichroic) gem, will exhibit emerald green, red and orange-yellow colors depending on viewing direction in partially polarised light. However, its most distinctive property is that it also changes color in artificial (tungsten/halogen) light compared to daylight. The color change from red to green is due to strong absorption of light in a narrow yellow portion of the spectrum, while allowing large bands of more blue-green and red wavelengths to be transmitted. Which of these prevails to give the perceived hue depends on the spectral balance of the illumination. Fine-quality alexandrite has a green to bluish-green color in daylight (relatively blue illumination of high color temperature), changing to a red to purplish-red color in incandescent light (relatively yellow illumination).[8] However, fine-color material is extremely rare. Less-desirable stones may have daylight colors of yellowish-green and incandescent colors of brownish red.[8]

Cymophane is popularly known as "cat's eye". This variety exhibits pleasing chatoyancy or opalescence that reminds one of the eye of a cat.[9] When cut to produce a cabochon, the mineral forms a light-green specimen with a silky band of light extending across the surface of the stone.

Occurrence

Chrysoberyl forms as a result of pegmatitic processes. Melting in the Earth's crust produces relatively low-density molten magma which can rise upwards towards the surface. As the main magma body cools, water originally present in low concentrations became more concentrated in the molten rock because it could not be incorporated into the crystallization of solid minerals. The remnant magma thus becomes richer in water, and also in rare elements that similarly do not fit in the crystal structures of major rock-forming minerals. The water extends the temperature range downwards before the magma becomes completely solid, allowing concentration of rare elements to proceed so far that they produce their own distinctive minerals. The resulting rock is igneous in appearance but formed at a low temperature from a water-rich melt, with large crystals of the common minerals such as quartz and feldspar, but also with elevated concentrations of rare elements such as beryllium, lithium, or niobium, often forming their own minerals; this is called a pegmatite. The high water content of the magma made it possible for the crystals to grow quickly, so pegmatite crystals are often quite large, which increases the likelihood of gem specimens forming.

Chrysoberyl can also grow in the country rocks near to pegmatites, when Be- and Al-rich fluids from the pegmatite react with surrounding minerals. Hence, it can be found in mica schists and in contact with metamorphic deposits of dolomitic marble. Because it is a hard, dense mineral that is resistant to chemical alteration, it can be weathered out of rocks and deposited in river sands and gravels in alluvial deposits with other gem minerals such as diamond, corundum, topaz, spinel, garnet, and tourmaline. When found in such placers, it will have rounded edges instead of sharp, wedge-shape forms. Much of the chrysoberyl mined in Brazil and Sri Lanka is recovered from placers, as the host rocks have been intensely weathered and eroded.

If the pegmatite fluid is rich in beryllium, crystals of beryl or chrysoberyl could form. Beryl has a high ratio of beryllium to aluminium, while the opposite is true for chrysoberyl. Both are stable with the common mineral quartz. For alexandrite to form, some chromium would also have had to be present. However, beryllium and chromium do not tend to occur in the same types of rock. Chromium is most common in mafic and ultramafic rocks in which beryllium is extremely rare. Beryllium becomes concentrated in felsic pegmatites in which chromium is almost absent. Therefore, the only situation where an alexandrite can grow is when Be-rich pegmatitic fluids react with Cr-rich country rock. This unusual requirement explains the rarity of this chrysoberyl variety.

Alexandrite

The alexandrite variety displays a color change dependent upon the nature of ambient lighting. Alexandrite results from small scale replacement of aluminium by chromium ions in the crystal structure, which causes intense absorption of light over a narrow range of wavelengths in the yellow region (520–620 nm)[10][11] of the visible light spectrum.[10] Because human vision is most sensitive to green light and least sensitive to red light, alexandrite appears greenish in daylight where the full spectrum of visible light is present, and reddish in incandescent light which emits less green and blue light.[10][12] This color change is independent of any change of hue with viewing direction through the crystal that would arise from pleochroism.[10]

Alexandrite from the Ural Mountains in Russia can be green by daylight and red by incandescent light. Other varieties of alexandrite may be yellowish or pink in daylight and a columbine or raspberry red by incandescent light.

Stones that show a dramatic color change and strong colors (e.g., red-to-green) are rare and sought-after,[8] but stones that show less distinct colors (e.g. yellowish green changing to brownish yellow) may also be considered "alexandrite" by gem labs such as the Gemological Institute of America.[13][14]

According to a popular but controversial story, alexandrite was discovered by the Finnish mineralogist Nils Gustaf Nordenskiöld (1792–1866), and named alexandrite in honor of the future Emperor of All Russia Alexander II Romanov. Nordenskiöld's initial discovery occurred as a result of an examination of a newly found mineral sample he had received from Perovskii, which he identified as emerald at first.[15][16] The first emerald mine had been opened in 1831. However, recent research suggests that the stone was discovered by Yakov Kokovin.[17]

Alexandrite 5 carats (1,000 mg) and larger were traditionally thought to be found only in the Ural Mountains, but have since been found in larger sizes in Brazil. Other deposits are located in India (Andhra Pradesh), Madagascar, Tanzania and Sri Lanka. Alexandrite in sizes over three carats are very rare. Today, several labs can produce synthetic lab-grown stones with the same chemical and physical properties as natural alexandrite. Several methods can produce flux-grown alexandrite, Czochralski (or pulled) alexandrite, and hydrothermally-produced alexandrite. Flux-grown gems are fairly difficult to distinguish from natural alexandrite as they contain inclusions that seem natural. Czochralski or pulled alexandrite is easier to identify because it is very clean and contains curved striations visible under magnification. Although the color change in pulled stones can be from blue to red, the color change does not truly resemble that of natural alexandrite from any deposit. Hydrothermal lab-grown alexandrite has identical physical and chemical properties to real alexandrite.[18]

Some gemstones falsely described as lab-grown synthetic alexandrite are actually corundum laced with trace elements (e.g., vanadium) or color-change spinel and are not actually chrysoberyl. As a result, they would be more accurately described as simulated alexandrite rather than "synthetic". This alexandrite-like sapphire material has been around for almost 100 years and shows a characteristic purple-mauve colour change, which does not really look like alexandrite because there is never any green.[19]

  • Alexandrite
  •  

    Rough alexandrite from Brazil

  •  

    Rough alexandrite under UV light

  •  

    Alexandrite step cut cushion, 26.75 cts. This stone is bluish green in daylight and purple red under incandescent light

  •  

    An alexandrite ring with diamonds

Cymophane

 
Fine-color cymophane with a sharp and centered eye

Translucent yellowish chatoyant chrysoberyl is called cymophane or cat's eye. Cymophane has its derivation also from the Greek words meaning 'wave' and 'appearance', in reference to the haziness that visually distorts what would normally be viewed as a well defined surface of a cabochon. This effect may be combined with a cat eye effect. In this variety, microscopic tubelike cavities or needle-like inclusions[20] of rutile occur in an orientation parallel to the c-axis, producing a chatoyant effect visible as a single ray of light passing across the crystal. This effect is best seen in gemstones cut in cabochon form perpendicular to the c-axis. The color in yellow chrysoberyl is due to Fe3+ impurities.

Although other minerals such as tourmaline, scapolite, corundum, spinel and quartz can form "cat's eye" stones similar in appearance to cymophane, the jewelry industry designates these stones as "quartz cat's eyes", or "ruby cat's eyes" and only chrysoberyl can be referred to as "cat's eye" with no other designation.

Gems lacking the silky inclusions required to produce the cat's eye effect are usually faceted. An alexandrite cat's eye is a chrysoberyl cat's eye that changes color. "Milk and honey" is a term commonly used to describe the color of the best cat's eyes. The effect refers to the sharp milky ray of white light normally crossing the cabochon as a center line along its length and overlying the honey-colored background. The honey color is considered to be top-grade by many gemologists but the lemon yellow colors are also popular and attractive. Cat's eye material is found as a small percentage of the overall chrysoberyl production wherever chrysoberyl is found.

Cat's eye became significantly more popular by the end of the 19th century when the Duke of Connaught gave a ring with a cat's eye as an engagement token; this was sufficient to make the stone more popular and increase its value greatly. Until that time, cat's eye had predominantly been present in gem and mineral collections. The increased demand in turn created an intensified search for it in Sri Lanka.[21]

See also

References

  1. ^ 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.
  2. ^ "Mineralienatlas - Fossilienatlas". from the original on 2 February 2017. Retrieved 20 January 2017.
  3. ^ Handbook of Mineralogy 2011-12-15 at the Wayback Machine
  4. ^ "Chrysoberyl: Chrysoberyl mineral information and data". from the original on 13 January 2017. Retrieved 20 January 2017.
  5. ^ a b Barthelmy, Dave. "Chrysoberyl Mineral Data". from the original on 19 February 2017. Retrieved 20 January 2017.
  6. ^ Rudler, Frederick William (1911). "Chrysoberyl" . In Chisholm, Hugh (ed.). Encyclopædia Britannica. Vol. 6 (11th ed.). Cambridge University Press. p. 320.
  7. ^ Klein, Cornelis; Cornelius S. Hurlbut, Jr. (1985). Manual of Mineralogy (20th ed.). New York: Wiley. ISBN 0-471-80580-7.
  8. ^ a b c "Alexandrite Quality Factors". from the original on 18 December 2016. Retrieved 20 January 2017.
  9. ^ Rudler, Frederick William (1911). "Cat's-Eye" . Encyclopædia Britannica. Vol. 5 (11th ed.). p. 537.
  10. ^ a b c d "Why does alexandrite appear to change color in sunlight and artificial light?". from the original on 14 July 2014. Retrieved 6 June 2014.
  11. ^ Xie, Fei; Cao, Yu; Ranchon, Cindy; Hart, Alan; Hansen, Robin; Post, Jeffrey E.; Whitney, Coralyn W.; Dawson-Tarr, Emma; Drew, Alan J.; Dunstan, David J. (April 9, 2020). "Explanation of the Colour Change in Alexandrites". Scientific Reports. 10 (1): 6130. Bibcode:2020NatSR..10.6130X. doi:10.1038/s41598-020-62707-3. PMC 7145866. PMID 32273534.
  12. ^ Xie, Fei; Cao, Yu; Ranchon, Cindy; Hart, Alan; Hansen, Robin; Post, Jeffrey E.; Whitney, Coralyn W.; Dawson-Tarr, Emma; Drew, Alan J.; Dunstan, David J. (April 9, 2020). "Explanation of the Colour Change in Alexandrites". Scientific Reports. 10 (1): 6130. Bibcode:2020NatSR..10.6130X. doi:10.1038/s41598-020-62707-3. PMC 7145866. PMID 32273534.
  13. ^ "Bonhams : Alexandrite and Platinum and Diamond Ring". from the original on 7 March 2016. Retrieved 20 January 2017.
  14. ^ "GIA - Report Check". from the original on 12 October 2016. Retrieved 20 January 2017.
  15. ^ ""Alexandrite or Diaphanite?". In Alexandrite Tsarstone Collectors Guide". 2006. from the original on 2007-10-12. Retrieved 2007-07-09.
  16. ^ Nordenskiöld N. Alexandrit oder Ural Chrysoberyll // Schriften der St.-Petersburg geschrifteten Russisch-Kaiserlichen Gesellschaft fuer die gesammte Mineralogie. 1842. Bd 1. S. 116-127.
  17. ^ Wise, Richard W. (2016). Secrets Of the Gem trade (Second ed.). Brunswick House Press. p. 93. ISBN 9780972822329.
  18. ^ Clark, Donald. "Is Synthetic Alexandrite Real Alexandrite?". International Gem Society. from the original on 2016-07-07. Retrieved 2016-09-21.
  19. ^ "Alexandrite Synthetics and Imitations, In Alexandrite Tsarstone Collectors Guide". 2006. from the original on 2008-05-30. Retrieved 2007-07-09.
  20. ^ "Mitchell, T. E. and Marder, J. M., "Precipitation in Cat's-Eye Chrysoberyl," Electron Microscopy Soc. Proceedings, 1982.
  21. ^ "U.S. Geological Survey, 1887, George Frederick Kunz, Cymophane, Cat's Eye as gemstone". 1887. from the original on 2007-07-11. Retrieved 2007-07-09.

External links

 
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August 21, 2023
chrysoberyl, mineral, gemstone, chrysoberyl, aluminate, beryllium, with, formula, beal2o4, name, chrysoberyl, derived, from, greek, words, χρυσός, chrysos, βήρυλλος, beryllos, meaning, gold, white, spar, despite, similarity, their, names, chrysoberyl, beryl, c. The mineral or gemstone chrysoberyl is an aluminate of beryllium with the formula BeAl2O4 5 6 The name chrysoberyl is derived from the Greek words xrysos chrysos and bhryllos beryllos meaning a gold white spar Despite the similarity of their names chrysoberyl and beryl are two completely different gemstones although they both contain beryllium Chrysoberyl is the third hardest frequently encountered natural gemstone and lies at 8 5 on the Mohs scale of mineral hardness between corundum 9 and topaz 8 7 ChrysoberylCyclic trilling of chrysoberylGeneralCategoryOxide mineralsFormula repeating unit BeAl2O4IMA symbolCbrl 1 Strunz classification4 BA 05Crystal systemOrthorhombicCrystal classDipyramidal mmm H M symbol 2 m 2 m 2 m Space groupPbnmUnit cella 5 481 A b 9 415 A c 4 428 A Z 4IdentificationColorVarious shades of green emerald green yellow blue brownish to greenish black may be raspberry red under incandescent light when chromian colorless pale shades of yellow green or red in transmitted lightCrystal habitCrystals tabular or short prismatic prominently striatedTwinningContact and penetration twins common often repeated forming rosette structuresCleavageDistinct on 110 imperfect on 010 poor on 001 FractureConchoidal to unevenTenacityBrittleMohs scale hardness8 5LusterVitreousStreakWhiteSpecific gravity3 5 3 84Optical propertiesBiaxial Refractive indexna 1 745 nb 1 748 ng 1 754PleochroismX red Y yellow orange Z emerald green2V angleMeasured 70 References 2 3 4 5 Major varietiesAlexandriteColor change green to redCymophaneChatoyantMain chrysoberyl producing countriesAn interesting feature of its crystals are the cyclic twins called trillings These twinned crystals have a hexagonal appearance but are the result of a triplet of twins with each twin oriented at 120 to its neighbors and taking up 120 of the cyclic trilling If only two of the three possible twin orientations are present a V shaped twin results Ordinary chrysoberyl is yellowish green and transparent to translucent When the mineral exhibits good pale green to yellow color and is transparent then it is used as a gemstone The three main varieties of chrysoberyl are ordinary yellow to green chrysoberyl cat s eye or cymophane and alexandrite Yellow green chrysoberyl was referred to as chrysolite during the Victorian and Edwardian eras which caused confusion since that name has also been used for the mineral olivine peridot as a gemstone that name is no longer used in the gemological nomenclature Alexandrite a strongly pleochroic trichroic gem will exhibit emerald green red and orange yellow colors depending on viewing direction in partially polarised light However its most distinctive property is that it also changes color in artificial tungsten halogen light compared to daylight The color change from red to green is due to strong absorption of light in a narrow yellow portion of the spectrum while allowing large bands of more blue green and red wavelengths to be transmitted Which of these prevails to give the perceived hue depends on the spectral balance of the illumination Fine quality alexandrite has a green to bluish green color in daylight relatively blue illumination of high color temperature changing to a red to purplish red color in incandescent light relatively yellow illumination 8 However fine color material is extremely rare Less desirable stones may have daylight colors of yellowish green and incandescent colors of brownish red 8 Cymophane is popularly known as cat s eye This variety exhibits pleasing chatoyancy or opalescence that reminds one of the eye of a cat 9 When cut to produce a cabochon the mineral forms a light green specimen with a silky band of light extending across the surface of the stone Contents 1 Occurrence 2 Alexandrite 3 Cymophane 4 See also 5 References 6 External linksOccurrence EditChrysoberyl forms as a result of pegmatitic processes Melting in the Earth s crust produces relatively low density molten magma which can rise upwards towards the surface As the main magma body cools water originally present in low concentrations became more concentrated in the molten rock because it could not be incorporated into the crystallization of solid minerals The remnant magma thus becomes richer in water and also in rare elements that similarly do not fit in the crystal structures of major rock forming minerals The water extends the temperature range downwards before the magma becomes completely solid allowing concentration of rare elements to proceed so far that they produce their own distinctive minerals The resulting rock is igneous in appearance but formed at a low temperature from a water rich melt with large crystals of the common minerals such as quartz and feldspar but also with elevated concentrations of rare elements such as beryllium lithium or niobium often forming their own minerals this is called a pegmatite The high water content of the magma made it possible for the crystals to grow quickly so pegmatite crystals are often quite large which increases the likelihood of gem specimens forming Chrysoberyl can also grow in the country rocks near to pegmatites when Be and Al rich fluids from the pegmatite react with surrounding minerals Hence it can be found in mica schists and in contact with metamorphic deposits of dolomitic marble Because it is a hard dense mineral that is resistant to chemical alteration it can be weathered out of rocks and deposited in river sands and gravels in alluvial deposits with other gem minerals such as diamond corundum topaz spinel garnet and tourmaline When found in such placers it will have rounded edges instead of sharp wedge shape forms Much of the chrysoberyl mined in Brazil and Sri Lanka is recovered from placers as the host rocks have been intensely weathered and eroded If the pegmatite fluid is rich in beryllium crystals of beryl or chrysoberyl could form Beryl has a high ratio of beryllium to aluminium while the opposite is true for chrysoberyl Both are stable with the common mineral quartz For alexandrite to form some chromium would also have had to be present However beryllium and chromium do not tend to occur in the same types of rock Chromium is most common in mafic and ultramafic rocks in which beryllium is extremely rare Beryllium becomes concentrated in felsic pegmatites in which chromium is almost absent Therefore the only situation where an alexandrite can grow is when Be rich pegmatitic fluids react with Cr rich country rock This unusual requirement explains the rarity of this chrysoberyl variety Alexandrite EditThe alexandrite variety displays a color change dependent upon the nature of ambient lighting Alexandrite results from small scale replacement of aluminium by chromium ions in the crystal structure which causes intense absorption of light over a narrow range of wavelengths in the yellow region 520 620 nm 10 11 of the visible light spectrum 10 Because human vision is most sensitive to green light and least sensitive to red light alexandrite appears greenish in daylight where the full spectrum of visible light is present and reddish in incandescent light which emits less green and blue light 10 12 This color change is independent of any change of hue with viewing direction through the crystal that would arise from pleochroism 10 Alexandrite from the Ural Mountains in Russia can be green by daylight and red by incandescent light Other varieties of alexandrite may be yellowish or pink in daylight and a columbine or raspberry red by incandescent light Stones that show a dramatic color change and strong colors e g red to green are rare and sought after 8 but stones that show less distinct colors e g yellowish green changing to brownish yellow may also be considered alexandrite by gem labs such as the Gemological Institute of America 13 14 According to a popular but controversial story alexandrite was discovered by the Finnish mineralogist Nils Gustaf Nordenskiold 1792 1866 and named alexandrite in honor of the future Emperor of All Russia Alexander II Romanov Nordenskiold s initial discovery occurred as a result of an examination of a newly found mineral sample he had received from Perovskii which he identified as emerald at first 15 16 The first emerald mine had been opened in 1831 However recent research suggests that the stone was discovered by Yakov Kokovin 17 Alexandrite 5 carats 1 000 mg and larger were traditionally thought to be found only in the Ural Mountains but have since been found in larger sizes in Brazil Other deposits are located in India Andhra Pradesh Madagascar Tanzania and Sri Lanka Alexandrite in sizes over three carats are very rare Today several labs can produce synthetic lab grown stones with the same chemical and physical properties as natural alexandrite Several methods can produce flux grown alexandrite Czochralski or pulled alexandrite and hydrothermally produced alexandrite Flux grown gems are fairly difficult to distinguish from natural alexandrite as they contain inclusions that seem natural Czochralski or pulled alexandrite is easier to identify because it is very clean and contains curved striations visible under magnification Although the color change in pulled stones can be from blue to red the color change does not truly resemble that of natural alexandrite from any deposit Hydrothermal lab grown alexandrite has identical physical and chemical properties to real alexandrite 18 Some gemstones falsely described as lab grown synthetic alexandrite are actually corundum laced with trace elements e g vanadium or color change spinel and are not actually chrysoberyl As a result they would be more accurately described as simulated alexandrite rather than synthetic This alexandrite like sapphire material has been around for almost 100 years and shows a characteristic purple mauve colour change which does not really look like alexandrite because there is never any green 19 Alexandrite Rough alexandrite from Brazil Rough alexandrite under UV light Alexandrite step cut cushion 26 75 cts This stone is bluish green in daylight and purple red under incandescent light An alexandrite ring with diamondsCymophane Edit Fine color cymophane with a sharp and centered eyeTranslucent yellowish chatoyant chrysoberyl is called cymophane or cat s eye Cymophane has its derivation also from the Greek words meaning wave and appearance in reference to the haziness that visually distorts what would normally be viewed as a well defined surface of a cabochon This effect may be combined with a cat eye effect In this variety microscopic tubelike cavities or needle like inclusions 20 of rutile occur in an orientation parallel to the c axis producing a chatoyant effect visible as a single ray of light passing across the crystal This effect is best seen in gemstones cut in cabochon form perpendicular to the c axis The color in yellow chrysoberyl is due to Fe3 impurities Although other minerals such as tourmaline scapolite corundum spinel and quartz can form cat s eye stones similar in appearance to cymophane the jewelry industry designates these stones as quartz cat s eyes or ruby cat s eyes and only chrysoberyl can be referred to as cat s eye with no other designation Gems lacking the silky inclusions required to produce the cat s eye effect are usually faceted An alexandrite cat s eye is a chrysoberyl cat s eye that changes color Milk and honey is a term commonly used to describe the color of the best cat s eyes The effect refers to the sharp milky ray of white light normally crossing the cabochon as a center line along its length and overlying the honey colored background The honey color is considered to be top grade by many gemologists but the lemon yellow colors are also popular and attractive Cat s eye material is found as a small percentage of the overall chrysoberyl production wherever chrysoberyl is found Cat s eye became significantly more popular by the end of the 19th century when the Duke of Connaught gave a ring with a cat s eye as an engagement token this was sufficient to make the stone more popular and increase its value greatly Until that time cat s eye had predominantly been present in gem and mineral collections The increased demand in turn created an intensified search for it in Sri Lanka 21 See also EditList of mineralsReferences Edit 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 Mineralienatlas Fossilienatlas Archived from the original on 2 February 2017 Retrieved 20 January 2017 Handbook of Mineralogy Archived 2011 12 15 at the Wayback Machine Chrysoberyl Chrysoberyl mineral information and data Archived from the original on 13 January 2017 Retrieved 20 January 2017 a b Barthelmy Dave Chrysoberyl Mineral Data Archived from the original on 19 February 2017 Retrieved 20 January 2017 Rudler Frederick William 1911 Chrysoberyl In Chisholm Hugh ed Encyclopaedia Britannica Vol 6 11th ed Cambridge University Press p 320 Klein Cornelis Cornelius S Hurlbut Jr 1985 Manual of Mineralogy 20th ed New York Wiley ISBN 0 471 80580 7 a b c Alexandrite Quality Factors Archived from the original on 18 December 2016 Retrieved 20 January 2017 Rudler Frederick William 1911 Cat s Eye Encyclopaedia Britannica Vol 5 11th ed p 537 a b c d Why does alexandrite appear to change color in sunlight and artificial light Archived from the original on 14 July 2014 Retrieved 6 June 2014 Xie Fei Cao Yu Ranchon Cindy Hart Alan Hansen Robin Post Jeffrey E Whitney Coralyn W Dawson Tarr Emma Drew Alan J Dunstan David J April 9 2020 Explanation of the Colour Change in Alexandrites Scientific Reports 10 1 6130 Bibcode 2020NatSR 10 6130X doi 10 1038 s41598 020 62707 3 PMC 7145866 PMID 32273534 Xie Fei Cao Yu Ranchon Cindy Hart Alan Hansen Robin Post Jeffrey E Whitney Coralyn W Dawson Tarr Emma Drew Alan J Dunstan David J April 9 2020 Explanation of the Colour Change in Alexandrites Scientific Reports 10 1 6130 Bibcode 2020NatSR 10 6130X doi 10 1038 s41598 020 62707 3 PMC 7145866 PMID 32273534 Bonhams Alexandrite and Platinum and Diamond Ring Archived from the original on 7 March 2016 Retrieved 20 January 2017 GIA Report Check Archived from the original on 12 October 2016 Retrieved 20 January 2017 Alexandrite or Diaphanite In Alexandrite Tsarstone Collectors Guide 2006 Archived from the original on 2007 10 12 Retrieved 2007 07 09 Nordenskiold N Alexandrit oder Ural Chrysoberyll Schriften der St Petersburg geschrifteten Russisch Kaiserlichen Gesellschaft fuer die gesammte Mineralogie 1842 Bd 1 S 116 127 Wise Richard W 2016 Secrets Of the Gem trade Second ed Brunswick House Press p 93 ISBN 9780972822329 Clark Donald Is Synthetic Alexandrite Real Alexandrite International Gem Society Archived from the original on 2016 07 07 Retrieved 2016 09 21 Alexandrite Synthetics and Imitations In Alexandrite Tsarstone Collectors Guide 2006 Archived from the original on 2008 05 30 Retrieved 2007 07 09 Mitchell T E and Marder J M Precipitation in Cat s Eye Chrysoberyl Electron Microscopy Soc Proceedings 1982 U S Geological Survey 1887 George Frederick Kunz Cymophane Cat s Eye as gemstone 1887 Archived from the original on 2007 07 11 Retrieved 2007 07 09 External links Edit Wikimedia Commons has media related to wbr Alexandrite and wbr Chrysoberyl Listen to this article 12 minutes source source This audio file was created from a revision of this article dated 26 March 2015 2015 03 26 and does not reflect subsequent edits Audio help More spoken articles Alexandrite display on YouTube Retrieved from https en wikipedia org w index php title Chrysoberyl amp oldid 1140064352 Cymophane, wikipedia, wiki, book, books, library,

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