Chromium(III) chloride

Structure

Anhydrous chromium(III) chloride adopts the YCl₃ structure, with Cr³⁺ occupying two thirds of the octahedral interstices in alternating layers of a pseudo-cubic close packed lattice of Cl⁻ ions. The absence of cations in alternate layers leads to weak bonding between adjacent layers. For this reason, crystals of CrCl₃ cleave easily along the planes between layers, which results in the flaky (micaceous) appearance of samples of chromium(III) chloride.

Chromium(III) chloride hydrates

Chromium(III) chlorides display the somewhat unusual property of existing in a number of distinct chemical forms (isomers), which differ in terms of the number of chloride anions that are coordinated to Cr(III) and the water of crystallization. The different forms exist both as solids, and in aqueous solutions. Several members are known of the series of [CrCl_3−n(H₂O)_n]^z+. The main hexahydrate can be more precisely described as [CrCl₂(H₂O)₄]Cl•2H₂O. It consists of the cation trans-[CrCl₂(H₂O)₄]⁺ and additional molecules of water and a chloride anion in the lattice. Two other hydrates are known, pale green [CrCl(H₂O)₅]Cl₂•H₂O and violet [Cr(H₂O)₆]Cl₃. Similar behaviour occurs with other chromium(III) compounds.

Preparation

Anhydrous chromium(III) chloride may be prepared by chlorination of chromium metal directly, or indirectly by carbothermic chlorination of chromium(III) oxide at 650–800 °C

Cr₂O₃ + 3 C + 3 Cl₂ → 2 CrCl₃ + 3 CO

It may also be prepared by treating the hexahydrate with thionyl chloride:

CrCl₃•6H₂O + 6 SOCl₂ → CrCl₃ + 6 SO₂ + 12 HCl

The hydrated chlorides are prepared by treatment of chromate with hydrochloric acid and methanol. In laboratory the hydrates are usually prepared by dissolving the chromium metal or chromium(III) oxide in hydrochloric acid.

Reactions

Slow reaction rates are common with chromium(III) complexes. The low reactivity of the d³ Cr³⁺ ion can be explained using crystal field theory. One way of opening CrCl₃ up to substitution in solution is to reduce even a trace amount to CrCl₂, for example using zinc in hydrochloric acid. This chromium(II) compound undergoes substitution easily, and it can exchange electrons with CrCl₃ via a chloride bridge, allowing all of the CrCl₃ to react quickly.

With the presence of some chromium(II), however, solid CrCl₃ dissolves rapidly in water. Similarly, ligand substitution reactions of solutions of [CrCl₂(H₂O)₄]⁺ are accelerated by chromium(II) catalysts.

With molten alkali metal chlorides such as potassium chloride, CrCl₃ gives salts of the type M₃CrCl₆ and K₃Cr₂Cl₉, which is also octahedral but where the two chromiums are linked via three chloride bridges.

Complexes with organic ligands

CrCl₃ is a Lewis acid, classified as "hard" according to the Hard-Soft Acid-Base theory. It forms a variety of adducts of the type [CrCl₃L₃]^z, where L is a Lewis base. For example, it reacts with pyridine (C
5H
5N) to form an adduct:

CrCl₃ + 3 C₅H₅N → CrCl₃(C₅H₅N)₃

Treatment with trimethylsilylchloride in THF gives the anhydrous THF complex:

CrCl₃^.(H₂O)₆ + 12 (CH₃)₃SiCl + 3 THF → CrCl₃(THF)₃ + 6 ((CH₃)₃Si)₂O + 12 HCl

Precursor to organochromium complexes

Chromium(III) chloride is used as the precursor to many organochromium compounds, for example bis(benzene)chromium, an analogue of ferrocene:

Phosphine complexes derived from CrCl₃ catalyse the trimerization of ethylene to 1-hexene.

Use in organic synthesis

One niche use of CrCl₃ in organic synthesis is for the in situ preparation of chromium(II) chloride, a reagent for the reduction of alkyl halides and for the synthesis of (E)-alkenyl halides. The reaction is usually performed using two moles of CrCl₃ per mole of lithium aluminium hydride, although if aqueous acidic conditions are appropriate zinc and hydrochloric acid may be sufficient.

Chromium(III) chloride has also been used as a Lewis acid in organic reactions, for example to catalyse the nitroso Diels-Alder reaction.

Dyestuffs

A number of chromium-containing dyes are used commercially for wool. Typical dyes are triarylmethanes consisting of ortho-hydroxylbenzoic acid derivatives.

Precautions

Although trivalent chromium is far less poisonous than hexavalent, chromium salts are generally considered toxic.