An optically pure P-alkene-ligated Ir^I complex

Chiral P-alkene ligands are attracting growing interest in the field of enantioselective catalysis (Defieber et al., 2008). For example, the alkene-phosphoramidite, (S)-(+)-N-(3,5-dioxa-4-phosphacyclohepta[2,1-a;3,4- a']dinaphthalen-4-yl)-dibenz[b,f]azepine, (1) (Briceño & Dorta, 2007; Mariz et al., 2008), was used as a ligand in the Ir-catalysed enantioselective formation of allylic amines from allylic alcohols (70% ee) (Defieber et al., 2007) and for the Rh-catalysed conjugate addition (CA) of arylboronic acids to enones with up to 99% ee (Drinkel et al., 2010). In the latter case, the fully characterized monomeric Rh precatalysts, (2), of composition [RhCl(κ¹-P-alkene)(κ²-P-alkene)] bearing two equivalents of P-alkene ligand (1), displayed exclusive cis coordination of the P atoms and a square-planar coordination environment. Roggen & Carreira (2010) recently described the crystal structure of a similar monomeric Ir iodo complex of composition [IrI(P-alkene)₂] bearing, in a trans arrangement, the achiral variant of the P-alkene ligand (1), i.e. featuring the 2,2'-biphenol motif instead of the chiral auxiliary (S)-binaphthol. This complex is a competent catalyst for the stereospecific substitution of chiral allylic alcohols with sulfamic acid to afford optically active allylic amines with enantiospecificities >98%. Breher et al. (2004) described a related crystal structure of an achiral [IrCl(P-alkene)₂] complex also displaying trans or axial positioning of the P atoms in the trigonal–bipyramidal coordination environment. We note that the aforementioned pentacoordinate Ir complexes are per se chiral, possessing stereogenic Ir centres, but obviously without the use of enantiodiscriminating auxiliaries they are obtained as racemates. Here, we disclose the crystal structure of such a complex that is optically pure. The enantiomerically pure ligand (S)-(1) was used to synthesize the title complex, (3), and to our surprise its formation was perfectly diastereospecific based on NMR spectroscopy [possible diastereomers are (M,S,S) and (P,S,S); see also the pair of enantiomers of (3) depicted in the scheme]. Single-crystal X-ray analysis then allowed us to determine the absolute configuration at Ir, which is (P).

The asymmetric unit of (3) contains two molecules of the Ir complex, two of benzene and two of pentane. The two independent molecules of the Ir complex have largely similar conformations (Fig. 1), with the largest differences being in the orientations of the binaphthyl rings as a result of different puckering of the seven-membered phosphadioxa rings. The Cremer & Pople (1975) puckering parameters for the seven-membered rings are listed in Table 2 and show that the total puckering amplitude, Q, is somewhat different for the two seven-membered rings in each independent Ir complex molecule, but that the pattern is similar across the two molecules. An overlay of the two molecules is shown in Fig. 2, which demonstrates that small variations in the ring puckering have a significant effect on the positions of the atoms at the remote ends of the naphthyl rings. The molecules are approximately C₂ symmetric about the Ir—Cl axis, although the different ring puckering in the two seven-membered rings diminishes the exactness of the fit to C₂ symmetry. In contrast, the corresponding Ir complex with biphenyl groups in the P-alkene ligands has crystallographic C₂ symmetry (Roggen & Carreira, 2010).

The coordination environment in the Ir complex of (3) can be considered as trigonal bipyramidal, with the P atoms in axial positions, and the equatorial positions occupied by the Cl atom and the two alkene functions, each of which may be considered as occupying a single site in the formal equatorial trigonal plane. This arrangement parallels the architectures reported by Roggen & Carreira (2010). In each of the independent molecules, the Ir atom lies well within the plane defined by the Cl atom and the four alkene C atoms. The maximum deviations of these six atoms from the mean plane are 0.028 (4) Å for atom C48 in molecule A and 0.081 (5) Å for atom C118 in molecule B. The P—Ir—X bond angles, where X is any equatorial atom, lie in the narrow range 85.66 (12)–94.16 (12)°. Taking the bisector, Y, of each alkene C—Ir—C angle as the effective `bond' position of the alkene group gives Cl—Ir—Y angles in the range 109.85 (12)–112.70 (13)° and Y—Ir—Y angles of 139.31 (17) and 136.10 (17)°. These angles are closer to those required for a trigonal–bipyramidal coordination geometry than those expected for a square-planar arrangement with the Cl atom at the apex, thus indicating that the former is a more suitable description of the coordination geometry of the Ir atoms in (3).

The alkene C—C bond lengths [1.447 (6)–1.453 (6) Å] compare well with those in the complexes reported by Breher et al. (2004) and Roggen & Carreira (2010), and are significantly longer than those of the coordinated alkene in Rh complex (2) [1.405 (9) Å; Drinkel et al., 2010] and the alkene function in the free ligand, (1) [1.34 (2) Å; Mariz et al., 2008], which suggests a relatively high π-basicity of Ir^I (Dewar, 1951; Chatt & Duncanson, 1953). The Ir—P [mean 2.274 (2) Å] and Ir—Cl [mean 2.4453 (15) Å] distances (Table 1), and the dihedral angles between the planes of the naphthyl rings within the binaphthyl units, which are in the range 56.24 (17)–64.62 (13)° across the four independent binaphthyl groups, all fall into the expected ranges [Standard reference?].

The four independent N atoms in the P-alkene ligands of (3) have distinctly pyramidal geometry, with the sum of the bond angles about the N atoms in the range 335.6 (5)–337.0 (5)°. In contrast, the corresponding N atom in the free ligand, (1), has a trigonal-planar geometry, subtending a bond-angle sum of 360 (1)° (Mariz et al., 2008). The pyramidalization of the ligand N atom in (3) is similar to that observed in the bidentate ligand of the Rh complex, (2) (Drinkel et al., 2010), and may be a consequence of steric strain introduced by the bidentate coordination to the Ir atom through the P and alkene C atoms, which effectively creates six-membered boat-shaped chelate rings. The bite angles of the four independent ligands in the structure, P—Ir—Y, where Y is the bisector of each allyl C—Ir—C angle, are in the range 86.51 (13)–87.90 (13)°. When viewed along the P—Ir bond, the P—N bond closely eclipses the Ir—Y vector. Drinkel et al. (2010) discussed the torsion angle Y···N—P···Z, where Z is the midpoint of the bond joining the two naphthyl units in the binaphthyl group. This torsion angle for the bidentate P-alkene ligand in (2) is approximately 180°, which indicates an anti conformation of the binaphthyl and alkene groups, whereas syn conformations are found in the free ligand and the monodentate ligand in (2). The absolute values of the corresponding torsion angles for (3) are in the range 170.8 (2)–179.1 (2)° and also indicate an anti conformation for the bidentate ligands, which is consistent with the previous observations.

The packing of the molecules is fairly unremarkable, with one of each of the independent benzene and pentane solvent molecules lying in narrow channels running parallel to the [010] direction. The remaining solvent molecules occupy interstices between the complex molecules. There are no π–π interactions, with the shortest distance between the centres of gravity of any aromatic rings being approximately 4.0 Å. The shortest contacts of the C—H···π and C—H···O types are also considered to be too long to be indicative of significant attractive interactions.

The use of complex (3) as an enantioselective catalyst for organic transformations is currently being investigated, and results will be published in due course.