[CrBr₂(NH₃)₄][CrBr₄(NH₃)₂], a new chromium(III) complex

There is ongoing interest in chromium(III) complexes, owing to the importance of chromium in catalytic processes and its magnetic and optical properties. The often-found sixfold coordination of Cr^III with an essentially octahedral ligand arrangement is due to the high stability of the d³ configuration. In particular, ammonia complexes are the most numerous Cr^III derivatives and the most extensively studied, including the pure ammine [Cr(NH₃)₆]³⁺, for example [Cr(NH₃)₆][CuCl₅] (Ohba et al., 1995), and the mixed ammine–acid types, [Cr(NH₃)_6-xA_x]^(3-x)+ (x = 0–6), for example trans-[Cr(NH₃)₄Cl₂]I (Brencic et al., 1985) and Hg₆As₄[CrBr₆]Br (Olenev et al., 2003).

The synthesis and crystal structure of the title novel compound trans-tetraamminedibromochromium(III) trans-diamminetetrabromochromate(III), [CrBr₂(NH₃)₄][CrBr₄(NH₃)₂], is the result of exploratory investigations of mixed ammine–acid Cr^III complexes. Although the trans-tetraamminedibromochromium(III) cation was first mentioned (but without a crystal-structure report) more than three decades ago (Glerup & Schäffer, 1976), the trans-diamminetetrabromochromate(III) anion is observed here for the first time. To the best of our knowledge, the occurrence of Cr^III both as a complex cation and a complex anion in one compound is extremely rare. The only cases are [Cr(NH₃)₆][Cr(CN)₆] (Nielsen et al., 1986) and [Cr(NH₃)₆][Cr(NH₃)₂F₄][BF₄]₂ (Göbbels & Meyer, 2000). [Cr(NH₃)₆][Cr(CN)₆] was crystallized from [Cr(NH₃)₆]³⁺ and [Cr(CN)₆]^3- in aqueous solution under mild conditions. However, when these ammonia and cyanide complexes are present in aqueous solution the formation of mixed ammine–acid complexes will not occur. [Cr(NH₃)₆][Cr(NH₃)₂F₄][BF₄]₂, on the other hand, was obtained by the reaction of elemental Cr, B and NH₄F at 573 K, resulting in the mixed ammine–acid anion [Cr(NH₃)₂F₄]^-. For the synthesis of the title compound, an alternative non-aqueous route was used, using Cr₂(NCN)₃ as a starting material, together with NH₄Br, and this provides a stable and `naked' Cr³⁺ cation. Thus, the structurally stable compound [CrBr₂(NH₃)₄][CrBr₄(NH₃)₂] is achieved as a function of the synthetic route. The title compound can be also considered as the first real mixed ammine–acid Cr^III cation–anion compound, namely, [Cr(NH₃)_6-xA_x][Cr(NH₃)_6-yB_y] (x/y = 1–5, x + y = 6).

The title compound crystallizes in the centrosymmetric triclinic space group P1. The two symmetry-independent Cr^III atoms from the [CrBr₂(NH₃)₄]⁺ cation and the [CrBr₄(NH₃)₂]^- anion are positioned on the 1d and 1g inversion centres, while the N and Br atoms are on general positions. In the complex anion, the Cr^III atom (Cr1) is bonded to two apical NH₃ groups and four equatorial Br^- ions (Fig. 1). In the complex cation, the Cr^III atom (Cr2) is surrounded by four equatorial NH₃ groups and two apical Br^- ions. The coordinations of the Cr^III ions deviate from regular octahedral symmetry due to the different Cr—N and Cr—Br bond lengths. Comparison of the two complex ions shows that the Cr—N lengths are quite similar and that the equatorial Cr—Br bonds exhibit slightly longer distances than the axial ones (Table 1). A rigid-body correction of both octahedral entities according to the procedure of Schomaker & Trueblood (1968) is possible and it yields, for the Cr1-based complex anion, rather small bond increases of 0.007 Å for the Br atoms and 0.005 Å for the N atoms (R = 0.043). For the Cr2-based complex cation, the increases are likewise small, namely ca 0.005–0.006 Å for both Br and N atoms (R = 0.066). Based on the bond angles around the Cr^III centres, both octahedral entities are very close to D_4h symmetry, despite the triclinic space group. There is seemingly no electronic reason to distort away from D_4h because of the d³ configuration.

The crystal structure can be considered a typical ionic one, with a distorted [CsCl] motif (Fig. 2). It is quite common for the CsCl structure to be adopted when both ions are similar in size, and this is also found for [Cr(NH₃)₆][Cr(CN)₆] (Nielsen et al., 1986). The elongation of the b axis (b/a = 1.15) is caused by the non-regular octahedral ions, with CrBr₂(NH₃)₄]⁺ a lengthened and [CrBr₄(NH₃)₂]^- a flattened octahedron.

Besides the dominating Coulomb attractions, neighbouring Cr^III complex ions are also connected to each other via numerous weak N—H···Br hydrogen bonds (Table 2). These are likely to be responsible for the fact that the c/a ratio is 1.67, such that the cations and anions are not able to approach each other more closely.