Synthesis, reactivity and structures of hafnium-containing homo- and hetero- (bi- and tri-) metallic alkoxides based on edge- and face-sharing bioctahedral alkoxometalate ligands

Abstract

Using [{Hf(OPr ⁱ ) ₄ (Pr ⁱ OH)} ₂ ] as a building-block precursor, a series of homo- and hetero-metallic alkoxides of hafnium has been prepared and characterised using elemental analyses, infrared, multinuclear ( ¹ H, ⁷ Li, ¹³ C and ¹¹³ Cd) NMR and single-crystal X-ray diffraction studies. The solid-state structure of [Hf ₂ (OPr ⁱ ) ₈ (Pr ⁱ OH) ₂ ] 1 reveals an edge-shared bioctahedral structure with the co-ordinated alcohol forming a hydrogen bridge across the dinuclear unit. The reactions of 1 with other nitrogen- or oxygen-containing donors gave monosubstituted products of the general formula [Hf ₂ (OPr ⁱ ) ₈ (Pr ⁱ OH)L] (L = C ₅ H ₅ N 2 or C ₄ H ₈ O ₂ 3) which retain the dinuclear edge-sharing bioctahedral structure as determined for 2 by X-ray crystallography. Compound 1 reacted (1:2) with LiBu ⁿ or LiOPr ⁱ to afford dimeric [{LiHf(OPr ⁱ ) ₅ } ₂ ] 4. The molecular structure of 4 can be conceived as a dianionic [Hf ₂ (OPr ⁱ ) ₁₀ ] ^2- unit that binds two Li ⁺ one on each side of the Hf–Hf vector which are additionally co-ordinated by the bridging OPr ⁱ groups to display a trigonal-pyramidal geometry at the lithium atoms. The Hf ₂ O ₆ Li ₂ core in 4 comprises two analogous seconorcubane subunits sharing a common face defined by a Hf ₂ O ₂ ring. Equimolar reaction of CuCl ₂ and [KHf ₂ (OPr ⁱ ) ₉ ] afforded the monomeric halide heterobimetallic derivative [CuHf ₂ Cl(OPr ⁱ ) ₉ ] 5. Compound 5 is paramagnetic and follows Curie law behaviour as inferred by a variable-temperature ¹ H NMR study. In the solid state its molecular geometry could be formally seen as a tetradentate interaction of the distorted confacial bioctahedron [Hf ₂ (OPr ⁱ ) ₉ ] ^- with a CuCl ⁺ fragment. Each Hf is six-co-ordinated; Cu is five-co-ordinated and displays a distorted trigonal-bipyramidal geometry. The reaction (1:1) of [CdHf ₂ I(OPr ⁱ ) ₉ ] with KSr(OPr ⁱ ) ₃ produced a new heterotermetallic derivative [{[Cd(OPr ⁱ ) ₃ ]Sr[Hf ₂ (OPr ⁱ ) ₉ ]} ₂ ] 6. This involves the switching of central metal atoms between the two precursors and the Hf ₂ (OPr ⁱ ) ₉ unit in 6 binds to Sr rather than Cd as anticipated. The centrosymmetric dimeric form of 6 is made up of a [Sr(µ-OPr ⁱ ) ₂ Cd(µ-OPr ⁱ ) ₂ Cd(µ-OPr ⁱ ) ₂ Sr] ²⁺ spirocyclic unit capped at both the ends by [Hf ₂ (OPr ⁱ ) ₉ ] ^- moieties.