reprinted from Bulgarian Zeolite Web

Good definition of zeolite:

Zeolite is allumosilicate with sceletal structure containing holes occupied by large ions and water molecules which have substantial freedom of movement. This leads to possibilities of ion-exchange and reversible dehydratation.

The zeolite minerals form the most numerous group of the silicate minerals - more than 40 mineral species. All they differ each from another by their structure and chemical composition. The zeolite frameworks are constructed by Si and Al oxide thetrahedrons, forming regular system of holes. The Si/Al ratio varies(1:1 - 6:1 - N:1), but is never less than 1. There are several isostructural zeolite minerals, having one and the same framework, but they have different zeolite chemistry (framework chemistry - Si/Al ratio and cationic chemistry - the cation content).

Some pictures of zeolite frameworks must be here

Overall chemical composition of the zeolites can be represented with the following oxide formula:

M_x/nO.Al₂O₃.xSiO₂.yH₂O or more precizely as
M_x/n[Al_xSi_y)_2(x+y)].pH₂O where :

• M are monovalent (Na,K,Li) and/or bivalent (Ca, Mg,Ba etc.) cations;
• n is the charge of the cations;
• 1 < y/x < 6;
• 1 < p/x < 4;

Main properties of the zeolites

• Water sorption/desoprtion
  
  The water molecules in the zeolite channels are bonded by the forces of dipole interactions to the cations, forming their close surrounding. The water from the zeolite crystals can be removed during thermal treatment, often called "thermal activation" or "dehydration". The dehydration process is equilibric and is depending on the temperature and the partial water pressure. The curve of the dehydration (water loss vs. temperature at a constant pressure) is informatible for the water state in the zeolite - the "wide porous" zeolites show wide temperature range of the dehydration starting at room temperature, when "narrow porous" zeolites show narrow and more distinguishable curves with the beginning of the dehydration process at higher temperatures. The overall water content in saturated state and the character of the dehydration depend not only to the zeolite framework type, but also to their cationic content.
  
  During the dehydration process the frameworks of some zeolites are changed irreverively. After these changes are observed, the ability of reverse water saturation ("rehydration") is lost permanently. That's why some zeolite types are consider as "thermostable" and the temperature of the framework destruction is cited as their thermostability.
  
  The dehydrated stable zeolites are very good water sorbents, especially at low partial pressure of water vapours. That's why they are used as dessicants in several industrial processes.
  
• Adsorption, molecular sieve effects
  
• Ion exchange
  
• Catalytical properties

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