In crystallography, water of crystallization or water of hydration or crystallization water is water that occurs in crystals. Water of crystallization is necessary for the maintenance of crystalline properties, but capable of being removed by sufficient heat. [1] It is the total weight of water retained by certain salts at a given temperature[2] and is mostly present in a definite (stoichiometric) ratio. Classically, "water of crystallization" refers to water that is found in the crystalline framework of a metal complex but which is not directly bonded to the metal ion.
Upon crystallization from water or moist solvents, many compounds incorporate water molecules in their crystalline frameworks.
Compared to inorganic salts, proteins crystallize with unusually large amounts of water in the crystal lattice. A water content of 50 % is not uncommon. The extended hydration shell is what allows the protein crystallographer to argue that the conformation in the crystal is not too far from the native conformation in solution.
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In molecular formulas water of crystallization can be denoted in different ways:
A salt with associated water of crystallization is known as a hydrate. The structure of hydrates can be quite elaborate, because of the existence of hydrogen bonds that define polymeric structures. [3] [4] Historically, the structures of many hydrates were unknown, and the dot in the formula of a hydrate was employed to specify the composition without indicating how the water is bound. Examples:
For many salts, the exact bonding of the water is unimportant because the water molecules are labilized upon dissolution. For example, an aqueous solution prepared from CuSO4•5H2O and anhydrous CuSO4 behave identically. Therefore, knowledge of the degree of hydration is important only for determining the equivalent weight: one mole of CuSO4•5H2O weighs more than one mole of CuSO4. In some cases, the degree of hydration can be critical to the resulting chemical properties. For example, anhydrous RhCl3 is not soluble in water and is relatively useless in organometallic chemistry whereas RhCl3•3H2O is versatile. Similarly, hydrated AlCl3 is a poor Lewis acid and thus inactive as a catalyst for Friedel-Crafts reactions. Samples of AlCl3 must therefore be protected from atmospheric moisture to preclude the formation of hydrates.
Crystals of the aforementioned hydrated copper sulfate consist of [Cu(H2O)4]2+ centers linked to SO42- ions. Copper is surrounded by six oxygen atoms, provided by two different sulfate groups and four molecules of water. A fifth water resides elsewhere in the framework but does not bind directly to copper. The cobalt iodide mentioned above occurs as [Co(H2O)6]2+ and I-. In tin chloride, each Sn(II) center is pyramidal (mean O/Cl-Sn-O/Cl angle is 83°) being bound to two chloride ions and one water. The second water in the formula unit is hydrogen-bonded to the chloride and to the coordinated water molecule. Water of crystallization is stabilized by electrostatic attractions, consequently hydrates are common for salts that contain +2 and +3 cations as well as -2 anions. In some cases, the majority of the weight of a compound arises from water. Glauber's salt, Na2SO4(H2O)10, is a white crystalline solid with greater than 50% water by weight.
Consider the case of nickel(II) chloride hexahydrate. This species has the formula NiCl2(H2O)6. Crystallographic analysis reveals that the solid consists of [trans-NiCl2(H2O)4] subunits that are hydrogen bonded to each other as well as two additional molecules of H2O. Thus 1/3 of the water molecules in the crystal are not directly bonded to Ni2+, and these might be termed "water of crystallization".
The water content of most compounds can be determined with a knowledge of its formula. An unknown sample can be determined through thermogravimetric analysis (TGA) where the sample is heated strongly, and the accurate weight of a sample is plotted against the temperature. The amount of water driven off is then divided by the molar mass of water to obtain the number of molecules of water bound to the salt.
Water is particularly common solvent to be found in crystals because it is small and polar. But all solvents can be found in some host crystals. Water is noteworthy because it is reactive, whereas other solvents such as benzene are considered to be chemically innocuous. Occasionally more than one solvent is found in a crystal, and often the stoichiometry is variable, reflected in the crystallographic concept of "partial occupancy." It is common and conventional for a chemist to "dry" a sample with a combination of vacuum and heat "to constant weight."
For other solvents of crystallization, analysis is conveniently accomplished by dissolving the sample in a deuterated solvent and analyzing the sample for solvent signals by NMR spectroscopy. Single crystal X-ray crystallography is often able to detect the presence of these solvents of crystallization as well.
In the table below are indicated the number of molecules of water per metal in various salts.[5]
Formula of hydrated metal halides |
Coordination sphere of the metal |
equivalents of water of crystallization that are not bound to M |
Remarks |
---|---|---|---|
VCl3(H2O)6 | trans-[VCl2(H2O)4]+ | two | |
VBr3(H2O)6 | trans-[VBr2(H2O)4]+ | two | bromides and chlorides are usually similar |
VI3(H2O)6 | [V(H2O)6]3+ | none | iodide competes poorly with water |
CrCl3(H2O)6 | trans-[CrCl2(H2O)4]+ | two | dark green isomer |
CrCl3(H2O)6 | [CrCl(H2O)5]2+ | one | blue-green isomer |
CrCl2(H2O)4 | trans-[CrCl2(H2O)4] | none | molecular |
CrCl3(H2O)6 | [Cr(H2O)6]3+ | none | violet isomer |
MnCl2(H2O)6 | trans-[MnCl2(H2O)4] | two | |
MnCl2(H2O)4 | cis-[MnCl2(H2O)4] | none | note cis molecular |
MnBr2(H2O)4 | cis-[MnBr2(H2O)4] | none | note cis molecular |
MnCl2(H2O)2 | trans-[MnCl4(H2O)2] | none | polymeric with bridging chloride |
MnBr2(H2O)2 | trans-[MnBr4(H2O)2] | none | polymeric with bridging bromide |
FeCl2(H2O)6 | trans-[FeCl2(H2O)4] | two | |
FeCl2(H2O)4 | trans-[FeCl2(H2O)4] | none | molecular |
FeBr2(H2O)4 | trans-[FeBr2(H2O)4] | none | molecular |
FeCl2(H2O)2 | trans-[FeCl4(H2O)2] | none | polymeric with bridging chloride |
CoCl2(H2O)6 | trans-[CoCl2(H2O)4] | two | |
CoBr2(H2O)6 | trans-[CoBr2(H2O)4] | two | |
CoBr2(H2O)4 | trans-[CoBr2(H2O)4] | none | molecular |
CoCl2(H2O)4 | cis-[CoCl2(H2O)4] | none | note: cis molecular |
CoCl2(H2O)2 | trans-[CoCl4(H2O)2] | none | polymeric with bridging chloride |
CoBr2(H2O)2 | trans-[CoBr4(H2O)2] | none | polymeric with bridging bromide |
NiCl2(H2O)6 | trans-[NiCl2(H2O)4] | two | |
NiCl2(H2O)4 | cis-[NiCl2(H2O)4] | none | note: cis molecular |
NiBr2(H2O)6 | trans-[NiBr2(H2O)4] | two | |
NiCl2(H2O)2 | trans-[NiCl2(H2O)4] | none | polymeric with bridging chloride |
CuCl2(H2O)2 | [CuCl4(H2O)2]2 | none | tetragonally distorted two long Cu-Cl distances |
CuBr2(H2O)4 | [CuBr4(H2O)2]n | two | tetragonally distorted two long Cu-Br distances |