Niobium(IV) chloride

Structure and properties

In the solid state, niobium(IV) chloride exists as chains of edge-sharing octahedra with alternating Nb-Nb distances of lengths 302.9 and 379.4 pm. The shorter distances correspond to Nb-Nb bonds, which result in the compound’s diamagnetism. Its structure is very similar to that of tungsten(IV) chloride.

Other coordination complexes with the formula NbCl₄L₂, such as tetrachlorobis(tetrahydrofuran) niobium, only form monomers resulting in one unpaired electron in the d_xy orbital, making the compounds paramagnetic.

Niobium chloride rapidly oxidizes and hydrolyzes in air to form niobium(V) oxide.

Preparation

Niobium(IV) chloride is typically produced by allowing elemental niobium and niobium(V) chloride crystals to react over several days in a temperature gradient, with the metal around 400 °C and the salt around 250 °C.

4 NbCl₅ + Nb → 5 NbCl₄

Niobium (IV) chloride can also prepared by a similar reduction of niobium pentachloride with powdered aluminium.

3 NbCl₅ + Al → 3 NbCl₄ + AlCl₃

A similar technique is also used in the synthesis of niobium(IV) bromide and tantalum(IV) chloride. Niobium(IV) iodide exists as well and may be synthesized by thermal decomposition of niobium(V) iodide.

At 400 °C NbCl₄ disproportiates:

2 NbCl₄ → NbCl₃ + NbCl₅

Reactions

The disproportiation of niobium(IV) chloride can be used to make tetrachlorobis(tetrahydrofuran) niobium, a useful synthon in Nb^IV chemistry due to the lability of the attached tetrahydrofuran ligands. This compound can be synthesized by first reacting NbCl₅ with aluminium in acetonitrile followed by addition of tetrahydrofuran to the resultant solid by the following reaction.

3 NbCl₅ + Al + 3 CH₃CN → 3 NbCl₄(NCCH₃)₃ + AlCl₃ 3 NbCl₄(NCCH₃)₃ + AlCl₃ + 3 C₄H₈O → 3 NbCl₄(thf)₂ + 9 MeCN + AlCl₃(thf)

Niobium chloride has been used in the syntheses of indazoles which can be used as LXR or Liver X receptor inhibitors.