Difference between revisions of "Zeolite"

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[[File:pc30270chabazite.jpg|thumb|Chabazite]]
 
[[File:pc30270chabazite.jpg|thumb|Chabazite]]
 
== Description ==
 
== Description ==
[[File:ps20510stilbite.jpg|thumb|stilbite]]
+
[[File:ps20510stilbite.jpg|thumb|Stilbite]]
 +
[[File:ph30217heulandite.jpg|thumb|Heulandite]]
 
A group of naturally occurring minerals composed of alkali-hydrated aluminum silicates. Examples are analcite, chabazite, heulandite, [[natrolite|natrolite]], phillipsite, scolecite, stilbite, and thomosonite. Zeolites are soft, fibril minerals with numerous interconnecting voids that can absorb water as well as other liquids and gases. Additionally, zeolites have an ion-exchange capability since its alkaline cations, such as calcium, are mobile and capable of switching with other cations that pass through the cavities. By varying pressure and heat, synthetic zeolite matrices can be prepared from [[silica|silicon dioxide]] and [[aluminum%20oxide|aluminum oxide]] with selected pore sizes and textures ranging from gelatinous to sand-like. Zeolites are used as [[absorbent|absorbents]], [[catalyst|catalysts]], [[desiccant|desiccants]], filters, [[ion%20exchange%20resin|ion exchange resins]], and [[molecular%20sieve|molecular sieves]].
 
A group of naturally occurring minerals composed of alkali-hydrated aluminum silicates. Examples are analcite, chabazite, heulandite, [[natrolite|natrolite]], phillipsite, scolecite, stilbite, and thomosonite. Zeolites are soft, fibril minerals with numerous interconnecting voids that can absorb water as well as other liquids and gases. Additionally, zeolites have an ion-exchange capability since its alkaline cations, such as calcium, are mobile and capable of switching with other cations that pass through the cavities. By varying pressure and heat, synthetic zeolite matrices can be prepared from [[silica|silicon dioxide]] and [[aluminum%20oxide|aluminum oxide]] with selected pore sizes and textures ranging from gelatinous to sand-like. Zeolites are used as [[absorbent|absorbents]], [[catalyst|catalysts]], [[desiccant|desiccants]], filters, [[ion%20exchange%20resin|ion exchange resins]], and [[molecular%20sieve|molecular sieves]].
  
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| 1.470-1.494
 
| 1.470-1.494
 
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== Additional Images ==
 
 
<gallery>
 
File:ph30217heulandite.jpg|Heulandite
 
</gallery>
 
  
 
==Resources and Citations==
 
==Resources and Citations==

Latest revision as of 09:51, 6 June 2022

Chabazite

Description

Stilbite
Heulandite

A group of naturally occurring minerals composed of alkali-hydrated aluminum silicates. Examples are analcite, chabazite, heulandite, Natrolite, phillipsite, scolecite, stilbite, and thomosonite. Zeolites are soft, fibril minerals with numerous interconnecting voids that can absorb water as well as other liquids and gases. Additionally, zeolites have an ion-exchange capability since its alkaline cations, such as calcium, are mobile and capable of switching with other cations that pass through the cavities. By varying pressure and heat, synthetic zeolite matrices can be prepared from silicon dioxide and Aluminum oxide with selected pore sizes and textures ranging from gelatinous to sand-like. Zeolites are used as absorbents, catalysts, desiccants, filters, ion exchange resins, and molecular sieves.

Synonyms and Related Terms

molecular sieve; Kaken gel; Nikka pellets; Arten gel; MicroChamber; chabazite; analcite; heulandite; natrolite; phillipsite; scolecite; stilbite; thomosonite; seolit (Dan.); Zeolith (Deut.); zeolita (Esp.); zéolithe (Fr.); zeoliet (Ned.); zeólito (Port.)

Raman

ChabaziteRS.jpg

Raman

Chabasiteitaly1.jpg

Raman

HeulanditeRS.jpg

Raman

StilbiteRS.jpg

Raman

Stilbiteitaly1.jpg


Physical and Chemical Properties

  • Hexagonal crystal system forming cube-like rhombohedrons.
  • Luster = vitreous.
  • Fracture = uneven.
  • Streak = white.
Composition Na2O.Al2O3.xSiO2.xH2O
Mohs Hardness 4.0 -5.0
Density 2.0-2.1 g/ml
Refractive Index 1.470-1.494

Resources and Citations

  • A. Dyer, "An Introduction to Zeolite Molecular Sieves', J. Wiley & Sons, London, 1988.° S. Rempel "Zeolite Molecular Traps and their use in Preventive Conservation ", WAAC Newsletter, Vol.18 No. 1 1996
  • G.S.Brady, Materials Handbook, McGraw-Hill Book Co., New York, 1971 Comment: p. 328
  • Walter C. McCrone, John Gustave Delly, The Particle Atlas, W. McCrone Associates, Chicago, IV, 1972
  • C.W.Chesterman, K.E.Lowe, Audubon Society Field Guide to North American Rocks and Minerals, Alfred A. Knopf, New York, 1979