1. Chemical context

Carbodi­phospho­ranes (CDPs), also termed double ylides, consist of two tertiary phosphines connected to a central divalent carbon(0) atom. The P—C bonds are best described as donor–acceptor inter­actions (Petz & Frenking, 2010). Most of the chemistry associated with CDPs concerns compounds with Lewis acids. Since the central CDP carbon possesses two lone electron pairs, it is therefore able to inter­act with either one or two Lewis acids (Chauvin & Canac, 2010; Petz & Frenking, 2010). Reactions involving the cleavage of the P—C bonds of the CDP functionality are less common in contrast to phospho­rus ylides (Petz & Frenking, 2010; Kolodiazhnyi, 1999). We hereby report the non-innocent reactivity (Poverenov & Milstein, 2013) of a PCP pincer ligand, whose central carbon is part of a CDP functionality, with an organic azide in the coordination sphere of iridium.

Treatment of the Ir^III PCP pincer CDP complex [Ir(Cl)(H)(C(dppm)₂-κ³P,C,P)(MeCN)]Cl (1a) (Schlapp-Hackl et al., 2018) with 1-azido-4-chloro­benzene affords the Ir^I complex [Ir((4-Cl-C₆H₄N₃)C(dppm)-κ³P,C,N)(dppm-κ²P,P′)]Cl (2). The reaction implies the substitution of one phosphine moiety of the PCP pincer ligand C(dppm)₂ for the organic azide, thus producing the triazeneyl­idene­phospho­rane (4-Cl-C₆H₄N₃)C(dppm), which acts as a PCN pincer ligand in 2. The phosphine displaced from the CDP functionality ends up in the coordination sphere of iridium and becomes part of a four-membered dppm chelate ring (see scheme).

We believe that the reaction is initiated by an inter­action of the electrophilic organic azide with the central CDP carbon of the PCP ligand, which disposes of one lone electron pair (Petz & Frenking, 2010). In a related reaction, N-heterocyclic carbenes (NHCs) have been reported to form end-on adducts with organic azides to form triazenes (Khramov & Bielawski, 2005). The inter­action of the CDP with the organic azide results in the formation of a double bond between the central carbon and the terminal nitro­gen of the organic azide and is associated with the cleavage of one P—C bond of the CDP functionality, while the carbon–iridium bond remains intact. At this stage, a deeply coloured and presumably five-coord­in­ate Ir^I inter­mediate was detected by monitoring the reaction via ³¹P-NMR spectroscopy. This inter­mediate features the triazenyl­idene­phospho­rane ligand (4-Cl-C₆H₄N₃)C(dppm) and a monodentate dppm unit. The absence of a hydrido ligand is attributed to an antecedent reductive elimination of hydro­chloric acid, which, according to NMR spectroscopic results, is absorbed by the CDP carbon of the starting complex 1a. This carbon atom turns out to be the strongest base of the system, apparently more basic than the nitro­gen atoms and the central carbon of the PCN pincer ligand of 2. Consequently, only 50% of the educt is converted to 2. However, an almost qu­anti­tative and fast conversion into 2 was achieved upon addition of basic alumina. The formation of 2 is finalized via the dissociation of a chlorido ligand and the coordination of the displaced phosphine functionality to the Ir centre.

Treatment of 1a with KCN affords [Ir(Cl)(CN)(H)((C(dppm)₂)-κ³P,C,P)] (1b), which reacts very slowly (over the course of weeks at room temperature) with 1-azido-4-chloro­benzene to the six-coordinate complex [Ir(CN)((4-Cl-C₆H₄N₃)CH(CH(PPh₂)₂)-κ³P,C,N)(dppm-κ²P,P′)] (3). Related to the formation of 2, the organic azide substitutes one phosphine of the CDP functionality.

At first sight, the resulting PCN pincer ligand of 3 looks like a tautomer of the PCN pincer ligand of 2: while in the PCN pincer of 3, one proton is attached to C1 and C2 respectively, the PCN pincer of 2 carries two protons at C2 and none at C1. In contrast to the neutral ligand of 2, the PCN ligand in 3 carries a double negative charge, deduced as follows: first, in view of coordination number 6, 3 constitutes an Ir^III complex. Second, the coordination compound 3 carries no charge. Third, the cyanido ligand contributes a −1 charge, and the iridium central atom a +3 charge. Since the dppm ligand is neutral, the charge of the PCN pincer ligand can be calculated to be −2. We suspect that the pathway of the reaction is similar to the formation of 2, except that the cyanido ligand permanently stays in the coordination sphere of iridium. The coordination of the displaced phosphine functionality to the Ir^I centre is thought to induce a two-electron transfer from iridium to the PCN ligand related to an oxidative addition reaction, and to be followed by the transfer of one proton from C2 to C1.

2. Structural commentary

The structures of compounds 2, 1b and 3 are given in Figs. 1, 2 and 3, respectively. Selected bond lengths and angles for all three compounds are given in Table 1.

Figure 1 Structure of 2 with displacement ellipsoids drawn at the 30% probability level. For clarity, only the ipso carbon atoms of the phenyl groups are shown, and solvent mol­ecules have been omitted.

Figure 2 Structure of 1b with displacement ellipsoids drawn at the 30% probability level. Only the ipso carbon atoms of the phenyl groups are shown for clarity, and solvent mol­ecules have been omitted.

Figure 3 Structure of 3 with displacement ellipsoids drawn at the 30% probability level. Only the ipso carbon atoms of the phenyl groups are shown for clarity.

The structure of 2 (Fig. 1) features a cationic five-coordinate iridium(I) complex with a chloride counter-ion. The asymmetric unit additionally contains 1.5 mol­ecules of di­chloro­methane and half a mol­ecule of toluene. The iridium centre is coordinated by a PCN pincer ligand and a chelating dppm; its coordination sphere displays a distorted trigonal–bipyramidal geometry, in which the PCN pincer occupies one axial (C1) and two equatorial (P1 and N1) positions. The donor atoms of the chelating dppm are found in the remaining axial (P3) and equatorial (P4) positions. Major distortions are apparent from the angles P4—Ir1—P3 [70.69 (5)°] and N1—Ir1—P1 [140.4 (1)°], which reflect the ring strain of both the four-membered dppm chelate ring and the PCN pincer ligand. The angles around the ylidic carbon C1 cover a range of 115.9 (4) to 124.5 (3)°, with a sum total of 359°. The C1=N3 bond exhibits an increased length [1.346 (7) Å] relative to typical C=N double bonds (1.29 Å), resulting in a formal bond order (BO) of 1.7. With a bond length of 1.308 (6) Å, the N2—N3 bond's BO is 1.7 as well; the N1—N2 distance amounts to 1.354 (6) Å (BO 1.5). In reported adducts of NHCs with organic azides, the C—N3 (numbering as in the free azides) bond lengths are similar to 2, whereas N1—N2 separations are shorter (ca 1.27 Å) and the N2—N3 distances are longer (ca 1.35 Å) compared to the corresponding bond lengths in 2 (Khramov & Bielawski, 2005). These differences are presumably due to the coordination of N3 to the Ir centre. Organic azides themselves exhibit a short N2—N3 bond [e.g. 1.1322 (2) Å, BO 2.5, for 2,4,6-trichlorphenyl­azide], whereas the N1—N2 bond is distinctly longer [1.252 (2) Å, BO 1.9; Takayama et al., 2010].

The structure of 1b (Fig. 2) displays an octa­hedral irid­ium(III) coordination compound with a meridional C(dppm)₂ PCP pincer ligand and one chlorido ligand situated trans to the central CDP carbon atom. The remaining sites are occupied by the hydrido and cyanido ligands positioned trans to each other. The structure is closely related to that of [Ir(Cl)₂(H)(C(dppm)₂)-κ³P,C,P)] (1c) (Partl et al., 2018), which contains one chlorido ligand instead of the cyanido ligand trans to the hydrido ligand. The introduction of the cyanido ligand results in a markedly shorter Ir1—Cl1 bond trans to the CDP carbon [2.445 (1) Å compared to 2.5157 (14) Å for 1c], whereas the Ir1—C1 separation becomes longer [2.128 (4)Å compared to 2.101 (5) Å]. Ir—P distances are marginally affected (Table 1).

The structure of 3 (Fig. 3) shows a six-coordinate iridium(III) coordination compound with the PCN pincer ligand [(4-Cl-C₆H₄N₃)CH(CH(PPh₂)₂)] in a facial mode, a bidentate dppm and a cyanido ligand trans to the central PCN carbon. Two mol­ecules of MeOH are connected to atoms N3 and N4 via hydrogen bonds. Distortions of the octa­hedral geometry are evident from the angles P3—Ir1—P4 and N1—Ir1—C1, amounting to 72.19 (2)° and 75.31 (9)°, respectively. The environment of the chiral carbon C1 is distorted tetra­hedral according to the angles N3—C1—Ir1 [109.8 (2)°], N3—C1—P2 [104.9 (2)°] and P2—C1—Ir1 [116.7 (1)°]. The deproton­ated dppm part of the PCN pincer ligand features delocal­ization over both P—C bonds [P1—C2 1.727 (3) and P2—C2 1.688 (3) Å, corresponding to a BO of ca 1.5 each). The C1—N3 bond is rather long [1.504 (3) Å, BO 0.8)] and appears to be in the range of protonated alkyl­amines, (Ishida, 2000) whereas the N2=N3 distance approximately corresponds to an N=N double bond [1.259 (3) Å, BO 1.9]. The N1—N2 separation is found to be in between a single and a double bond [1.347 (3) Å, BO 1.5].

3. Supra­molecular features

In the crystal of 2, supra­molecular features appear to revolve around the chloride anion (Table 2): Cl1 interacts with the methyl­ene group of one dppm unit (C2—H2B⋯Cl1 = 2.62 Å) and to a proton of one di­chloro­methane mol­ecule (C11—H11B⋯Cl1ⁱ = 2.49 Å). It must be mentioned, however, that due to the positional disorder of both the chloride anion and the di­chloro­methane solvate units, these `bond' lengths are an estimation and may not necessarily reflect any actual inter­molecular inter­actions.

Table 2 Hydrogen-bond geometry (Å, °) for 2 D—H⋯A D—H H⋯A D⋯A D—H⋯A C2—H2B⋯Cl1 0.98 2.62 3.5215 (1) 153 C11—H11B⋯Cl1i 0.98 2.49 3.4594 (1) 170 C209—H209⋯N3ii 0.94 2.60 3.3722 (1) 140 C306—H306⋯Cl1Aiii 0.94 2.81 3.7037 (1) 159 Symmetry codes: (i) ; (ii) ; (iii) .

In the crystal of 1b, the nitro­gen atom of the aceto­nitrile solvate interacts with the methyl­ene group of one dppm unit in a hydrogen-bond like manner (C3—H3B⋯N2 = 2.58 Å; Table 3). Inter­molecular halogen–hydrogen inter­actions are observed in two instances between phenyl protons and the chlorido ligand (C102—H102⋯Cl1 = 2.66 Å and C112—H112⋯Cl1ⁱ = 2.77 Å; Table 3).

Table 3 Hydrogen-bond geometry (Å, °) for 1b D—H⋯A D—H H⋯A D⋯A D—H⋯A C3—H3B⋯N2 0.98 2.58 3.4925 (1) 156 C102—H102⋯Cl1 0.94 2.66 3.5216 (1) 153 C112—H112⋯Cl1i 0.94 2.77 3.6470 (1) 155 C210—H210⋯N2ii 0.94 2.61 3.4554 (1) 150 C303—H303⋯N1iii 0.94 2.48 3.2064 (1) 134 Symmetry codes: (i) ; (ii) ; (iii) -x+2, -y+1, -z+1.

In the crystal of 3, inter­molecular features are restricted to solvate coordination (Table 4): both methanol units are connected to the complex via hydrogen bonds, one to the triazenido group (O2—H2A⋯N3 = 2.16 Å) and the other to the cyanido ligand (O1—H1A⋯N4 = 2.02 Å).

4. Synthesis and crystallization

The syntheses of the title compounds are summarized in the general reaction scheme for the synthesis and crystallization of 2, 1b and 3, starting from 1a (1c is only mentioned for comparative purposes – see Structural commentary). All preparations were carried out under an inert atmosphere (N₂) using standard Schlenk techniques. ¹H, ¹³C and ³¹P NMR spectra were recorded on a Bruker DPX 300 NMR spectrometer (300 MHz) and were referenced against ¹³C/¹H solvent peaks or an external 85% H₃PO₄ standard, respectively. The phospho­rus atoms in the NMR data are labelled in the same way as in the figures.

Synthesis of complex 2: 1a is formed upon stirring a mixture of [IrCl(cod)]₂ (8.5 mg, 0.0125 mmol), [CH(dppm)₂]Cl (20.5 mg, 0.025 mmol), (Reitsamer et al., 2012), MeCN (0.1 ml) and MeOH (0.5 ml) for 25 min. After this, a solution of 1-azido-4-chloro­benzene (0.5 mol L⁻¹ in methyl-tert-butyl ether, 0.1 ml, 0.050 mmol) and basic Al₂O₃ (30 mg) were subsequently added and the suspension was stirred for 5 min. The liquid part was separ­ated, and the volatiles evaporated in vacuo. The residue was then dissolved in CH₂Cl₂/toluene 1:2. Slow evaporation gave crystalline 2.

³¹P{¹H}-NMR (MeCN/MeOH 1:5): δ = 16.1 (P1, ddd; J_P1P2 = 30.6, J_P1P3 = 6.1, J_P1P4 = 33.7 Hz); 15.6 (P2, ddd; J_P2P3 = 44.4, J_P2P4 = 13.8 Hz); −37.4 (P3, ddd; J_P3P4 = 52.0 Hz); −20.9 (P4, ddd) ppm. ¹³C{¹H}-NMR (MeCN/MeOH 1:5): δ = 169.5 (C1, dddd; J_C1P1 = 2.5, J_C1P2 = 60.0, J_C1P3 = 85.0, J_C1P4 = 8.3 Hz) ppm.

Synthesis of coordination compounds 1b and 3: A mixture of [IrCl(cod)]₂ (8.5 mg, 0.0125 mmol), [CH(dppm)₂]Cl (20.5 mg, 0.025 mmol), MeCN (0.1 ml) and MeOH (0.4 ml) was stirred for 25 min. Then, a solution of KCN (2 mg, 0.03 mmol) in MeOH (0.2 ml) was added and the mixture stirred for 1 min. Thereafter, a solution of 1-azido-4-chloro­benzene in MTBE (0.1 ml, mol L⁻¹ in MTBE, 0.05 mmol) was added. Yellow crystals of 1b formed within a few hours. Within 14 d, the orange crystals of 1b disappeared, and colourless crystals of 3 had developed.

1b ³¹P{¹H}-NMR (MeCN/MeOH 1:6): δ = −0.3 (P1/P4, vt, N_P1/P4P2/P3 = 67.3 Hz); 28.2 (P2/P3, vt) ppm. ¹³C{¹H}-NMR (MeCN/MeOH 1:6): δ = −36.5 (C1, t, J_C1P2/P3 = 100.1 Hz) ppm. ¹H-NMR (MeCN/MeOH 1:6): δ = −12.2 (H1, s, 1H) ppm.

3 ³¹P{¹H}-NMR (CHCl₃/MeOH 1:1): δ = 0.3 (P1, ddd, J_P1P2 = 153.0, J_P1P3 = 376.3, J_P1P4 = 18.4 Hz); 55.2 (P2, dd, J_P2P3 = 49.0 Hz); −57.0 (P3, ddd, J_P3P4 = 27.5 Hz); −67.1 (P4, dd) ppm. ¹³C-NMR (CHCl₃/MeOH 1:1): δ = 72.2 (C1, dd, J_C1P2 = 38.7, J_C1H1 = 142.1 Hz) ppm.

5. Refinement

Crystal data, data collection and structure refinement details are summarized in Table 5. Complex 2 involves a 2:1 positional disorder of the anion Cl1:Cl1A. The solvent mol­ecules CH₂Cl₂ and C₇H₈ show occupational disorder, with the toluene mol­ecule exhibiting additional 1:1 positional disorder with some nearly overlying carbon atoms. We propose a correlation between CH₂Cl₂ and C₇H₈, because of short inter­molecular Cl⋯C contacts. Therefore, the two solvent mol­ecules Cl3/C10–Cl4 and Cl5/C11–Cl6 have an occupancy of 0.75 and the `two' toluene mol­ecules, C12–C18 and C19–C25, an occupancy of 0.25. Several bond restraints were used to refine the toluene carbon atoms reasonably isotropically. The hydride hydrogen of 1b was localized and refined isotropically without restraints. The hydrogen atoms at C1 and C2 of 3 were localized and refined with isotropic displacement parameters. All other H atoms were positioned geometrically (C—H = 0.94–0.98 Å) and refined as riding with U_iso(H) = 1.2–1.5U_eq(C).

Table 5 Experimental details   1b 2 3 Crystal data Chemical formula [Ir(CN)ClH(C51H44P4)]·C2H3N [Ir(C25H22P2)(C32H26ClN3P2)]Cl·0.5C7H8·1.5CH2Cl2 [Ir(CN)(C23H22P2)(C34H26ClN3P2)]·2CH4O Mr 1076.47 1335.42 1216.61 Crystal system, space group Monoclinic, P21/n Orthorhombic, Pbcn Triclinic, P Temperature (K) 233 233 223 a, b, c (Å) 18.3264 (3), 13.6459 (2), 19.3010 (4) 28.1283 (3), 19.0989 (2), 23.6339 (2) 11.1683 (1), 12.7805 (2), 20.0591 (3) α, β, γ (°) 90, 101.803 (1), 90 90, 90, 90 98.475 (1), 93.122 (1), 109.336 (1) V (Å3) 4724.74 (14) 12696.6 (2) 2655.75 (6) Z 4 8 2 Radiation type Mo Kα Mo Kα Mo Kα μ (mm−1) 3.06 2.45 2.73 Crystal size (mm) 0.18 × 0.07 × 0.02 0.3 × 0.2 × 0.15 0.31 × 0.30 × 0.12   Data collection Diffractometer Nonius KappaCCD Nonius KappaCCD Nonius KappaCCD No. of measured, independent and observed [I > 2σ(I)] reflections 25915, 8317, 6345 73594, 11155, 9002 20072, 10396, 9895 Rint 0.086 0.039 0.034 (sin θ/λ)max (Å−1) 0.595 0.595 0.617   Refinement R[F2 > 2σ(F2)], wR(F2), S 0.040, 0.069, 1.03 0.042, 0.126, 1.05 0.023, 0.056, 1.05 No. of reflections 8317 11155 10396 No. of parameters 564 724 661 No. of restraints 0 30 0 H-atom treatment H atoms treated by a mixture of independent and constrained refinement H-atom parameters constrained H atoms treated by a mixture of independent and constrained refinement Δρmax, Δρmin (e Å−3) 0.56, −1.04 1.66, −0.73 0.77, −1.11 Computer programs: COLLECT (Nonius, 1998), DENZO and SCALEPACK (Otwinowski & Minor, 1997), SHELXS97 (Sheldrick, 2008), SHELXL2014 (Sheldrick, 2015), Mercury (Macrae et al., 2008) and publCIF (Westrip, 2010).