Hafnium(IV) chloride is the inorganic compound with the formula HfCl<sub>4</sub>. This colourless solid is the precursor to most hafnium organometallic compounds. It has a variety of highly specialized applications, mainly in materials science and as a catalyst.
HfCl<sub>4</sub> can be produced by several related procedures:
Hafnium and zirconium occur together in minerals such as zircon, cyrtolite and baddeleyite. Zircon contains 0.05% to 2.0% hafnium dioxide HfO<sub>2</sub>, cyrtolite with 5.5% to 17% HfO<sub>2</sub> and baddeleyite contains 1.0 to 1.8 percent HfO<sub>2</sub>. Hafnium and zirconium compounds are extracted from ores together and converted to a mixture of the tetrachlorides.
The separation of HfCl<sub>4</sub> and ZrCl<sub>4</sub> is difficult because the compounds of Hf and Zr have very similar chemical and physical properties. Their atomic radii are similar: the atomic radius is 156.4 pm for hafnium, whereas that of Zr is 160 pm. These two metals undergo similar reactions and form similar coordination complexes.
A number of processes have been proposed to purify HfCl<sub>4</sub> from ZrCl<sub>4</sub> including fractional distillation, fractional precipitation, fractional crystallization and ion exchange. The log (base 10) of the vapor pressure of solid hafnium chloride (from 476 to 681 K) is given by the equation: log<sub>10</sub> P = âÂÂ5197/T + 11.712, where the pressure is measured in torrs and temperature in kelvins. (The pressure at the melting point is 23,000 torrs.)
One method is based on the difference in the reducibility between the two tetrahalides. The tetrahalides can in be separated by selectively reducing the zirconium compound to one or more lower halides or even zirconium. The hafnium tetrachloride remains substantially unchanged during the reduction and may be recovered readily from the zirconium subhalides. Hafnium tetrachloride is volatile and can therefore easily be separated from the involatile zirconium trihalide.
This group 4 halide contains hafnium in the +4 oxidation state. Solid HfCl<sub>4</sub> is a polymer with octahedral Hf centers. Of the six chloride ligands surrounding each Hf centre, two chloride ligands are terminal and four bridge to another Hf centre. In the gas phase, both ZrCl<sub>4</sub> and HfCl<sub>4</sub> adopt the monomeric tetrahedral structure seen for TiCl<sub>4</sub>. Electronographic investigations of HfCl<sub>4</sub> in gas phase showed that the Hf-Cl internuclear distance is 2.33 ÃÂ and the Cl...Cl internuclear distance is 3.80 ÃÂ . The ratio of intenuclear distances r(Me-Cl)/r(Cl...Cl) is 1.630 and this value agrees well with the value for the regular tetrahedron model (1.633).
The compound hydrolyzes, evolving hydrogen chloride:
Aged samples thus often are contaminated with oxychlorides, which are also colourless.
THF forms a monomeric 2:1 complex:
Because this complex is soluble in organic solvents, it is a useful reagent for preparing other complexes of hafnium.
HfCl<sub>4</sub> undergoes salt metathesis with Grignard reagents. In this way, tetrabenzylhafnium can be prepared.
Similarly, salt metathesis with sodium cyclopentadienide gives hafnocene dichloride:
With alcohols, alkoxides are formed.
These compounds adopt complicated structures.
Reduction of HfCl<sub>4</sub> is especially difficult. In the presence of phosphine ligands, reduction can be effected with sodiumâÂÂpotassium alloy:
The deep green dihafnium product is diamagnetic. X-ray crystallography shows that the complex adopts an edge-shared bioctahedral structure, very similar to the Zr analogue.
Hafnium tetrachloride is the precursor to highly active catalysts for the Ziegler-Natta polymerization of alkenes, especially propylene. Typical catalysts are derived from tetrabenzylhafnium.
HfCl<sub>4</sub> is an effective Lewis acid for various applications in organic synthesis. For example, ferrocene is alkylated with allyldimethylchlorosilane more efficiently using hafnium chloride relative to aluminium trichloride. The greater size of Hf may diminish HfCl<sub>4</sub>'s tendency to complex to ferrocene.
HfCl<sub>4</sub> increases the rate and control of 1,3-dipolar cycloadditions. It was found to yield better results than other Lewis acids when used with aryl and aliphatic aldoximes, allowing specific exo-isomer formation.
HfCl<sub>4</sub> was considered as a precursor for chemical vapor deposition and atomic layer deposition of hafnium dioxide and hafnium silicate, used as high-ú dielectrics in manufacture of modern high-density integrated circuits. However, due to its relatively low volatility and corrosive byproducts (namely, HCl), HfCl<sub>4</sub> was phased out by metal-organic precursors, such as tetrakis ethylmethylamino hafnium (TEMAH).