Difference between revisions of "Maxixe"

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Maxixe (pron. Mah-she-she) is the almost [[Sapphire]] color variety of [[Beryl]]. It was discovered in 1917 in the Maxixe mine in the Piaui area south of Arassuahy, Minas Gerais, Brazil. Maxixe owes it's very unstable color due to natural irradiation which causes a color center that is most probably caused in the NO<sub>3</sub> sites. When exposed to sunlight or temperatures above 100° C. it will rapidly loose its color, which can be restored by gamma irradiation and heating.<br />
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Maxixe (pronounced Mah-she-she) is the almost-[[sapphire]] color variety of [[beryl]]. It was discovered in 1917 in the Maxixe mine in the Piaui area south of Arassuahy, Minas Gerais, Brazil. Maxixe owes it's very unstable color due to natural irradiation that causes a [[Causes_of_color#Color_centers|color center]] most probably in the NO<sub>3</sub> sites. When exposed to sunlight or temperatures above 100° C, it will rapidly lose its color. Color can be restored by irradiation (gamma, x-ray or neutron) and annealing.<br />
As of 1973 some dark-blue Beryls started appearing on the market again and research showed that the color was also due to irradiation (artificial), the color center in this case proved to be CO<sub>3</sub>. This new type was named "Maxixe-type" Beryl. This type of Beryl has a very unstable color like Maxixe aswell. The starting color of these stones were yellow or green Beryls.<br />
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As of around 1970, some dark-blue beryls started appearing on the market again and research showed that the color was also due to irradiation (artificial), but the color center in this case proved to be in the CO<sub>3</sub> sites. This new type was named "Maxixe-type" beryl and, like Maxixe, it is a very unstable color. The original color of these beryls was yellow or green.<br />
There are also bi-colored Maxixe-type Beryls (yellow/blue) and their color is attributed to artificial irradiation on specimens that have uneven distribution of impurities.
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There are also bi-colored Maxixe-type beryls (yellow/blue). Their color is attributed to artificial irradiation on specimens that have uneven distribution of impurities.
  
The impurities found in Maxixe and Maxixe-type Beryl are Cs, Zn, Li, Rb, B and high Fe content.
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The impurities found in Maxixe and Maxixe-type beryl are Cs, Zn, Li, Rb, B and high concentrations of Fe.
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As the color is mainly caused by a color center, this is not an aquamarine beryl but a variety on its own.<br />
 +
Both the nitrate and carbonate varieties can be irradiated by natural and artificial means, and their distinction is not possible with standard gemological instruments. Therefore, Kurt Nassau suggested dropping the Maxixe-type nomenclature and name both Maxixe.
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 +
Maxixe and Maxixe-type beryl have stronger dichroic colors in the ordinary ray, while aquamarine has the stronger dichroic
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color in the extra-ordinary ray. Classification based on this is not viable, as [[heliodor]] may also have the stronger dichroic color in the ordinary ray. Thus it is not a characteristic feature of Maxixe beryl.
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==Diagnostics==
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===Spectrum===
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[[Image:Maxixe spectrum.jpg|left|thumb|400px|Spectrophotometer recording of maxixe beryl, by Bear Williams.]]
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<br clear="all" />
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==Sources==
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* ''On the identification and fade testing of Maxixe beryl ..'' - Kurt Nassau, The Journal of Gemmology (April 1996)
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==Additional Information on Maxixe Beryl==
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* http://www.mindat.org/min-10019.html <br/>
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* http://www.minsocam.org/ammin/AM61/AM61_100.pdf <br/>
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Found material on a bi-color maxixe beryl:
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* http://www.gaaj-zenhokyo.co.jp/researchroom/kanbetu/2004/kan_2004_02en.html <br/>
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Deposit reported in 2003 in the Yukon: but this article mentions they weren't sure if it were maxixe:<br/>
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* http://www.cbc.ca/health/story/2003/08/28/gem_rare030828.html
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GIA article:
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* http://gia.metapress.com/content/17u210387m035644/fulltext.pdf

Latest revision as of 21:40, 26 January 2015

Maxixe beryl
Chemical composition Be3Al2(SiO3)6 Beryllium aluminum silicate
Crystal system Hexagonal
Habit Prismatic
Cleavage Poor, basal
Fracture Conchoidal to uneven
Hardness 7.5
Optic nature Uniaxial -
Refractive index 1.579 - 1.592
Birefringence 0.007
Dispersion Low, 0.0014
Specific gravity 2.69 - 2.8
Lustre Vitreous
Pleochroism Distinct

Maxixe (pronounced Mah-she-she) is the almost-sapphire color variety of beryl. It was discovered in 1917 in the Maxixe mine in the Piaui area south of Arassuahy, Minas Gerais, Brazil. Maxixe owes it's very unstable color due to natural irradiation that causes a color center most probably in the NO3 sites. When exposed to sunlight or temperatures above 100° C, it will rapidly lose its color. Color can be restored by irradiation (gamma, x-ray or neutron) and annealing.
As of around 1970, some dark-blue beryls started appearing on the market again and research showed that the color was also due to irradiation (artificial), but the color center in this case proved to be in the CO3 sites. This new type was named "Maxixe-type" beryl and, like Maxixe, it is a very unstable color. The original color of these beryls was yellow or green.
There are also bi-colored Maxixe-type beryls (yellow/blue). Their color is attributed to artificial irradiation on specimens that have uneven distribution of impurities.

The impurities found in Maxixe and Maxixe-type beryl are Cs, Zn, Li, Rb, B and high concentrations of Fe.

As the color is mainly caused by a color center, this is not an aquamarine beryl but a variety on its own.
Both the nitrate and carbonate varieties can be irradiated by natural and artificial means, and their distinction is not possible with standard gemological instruments. Therefore, Kurt Nassau suggested dropping the Maxixe-type nomenclature and name both Maxixe.

Maxixe and Maxixe-type beryl have stronger dichroic colors in the ordinary ray, while aquamarine has the stronger dichroic color in the extra-ordinary ray. Classification based on this is not viable, as heliodor may also have the stronger dichroic color in the ordinary ray. Thus it is not a characteristic feature of Maxixe beryl.

Diagnostics

Spectrum

Spectrophotometer recording of maxixe beryl, by Bear Williams.


Sources

  • On the identification and fade testing of Maxixe beryl .. - Kurt Nassau, The Journal of Gemmology (April 1996)

Additional Information on Maxixe Beryl

Found material on a bi-color maxixe beryl:

Deposit reported in 2003 in the Yukon: but this article mentions they weren't sure if it were maxixe:

GIA article: