1. Chemical context

Carbodi­phospho­ranes (CDP) in combination with transition metals initialize a huge variety of functionalities. As a result of the presence of two σ-electron-donor groups, preferred in the form of tertiary phosphines, the stabilization of two free-electron pairs with σ- and simultaneously π-symmetry, the establishment of a localized electron octet and further the creation of a zero-valent, naked carbon atom in an excited singlet (¹D) state is possible (Petz & Frenking, 2010). The carbodi­phospho­rane C atom can be considered as a four-electron donor, and accordingly enables the coordination of two Lewis acids, such as protons or different metal cations. Our inter­ests focus on the combination of a carbodi­phospho­rane pincer ligand system, [CH(dppm)₂]Cl (dppm = 1,1-bis­(di­phenyl­phosphino)methane; Reitsamer et al., 2012), with reactive functionalities to enter new reaction pathways, to create new complexes and to analyse in detail the new properties obtained. In general, C—C coupling reactions can be induced via the use of diazo compounds such as ethyl diazo­acetate. As a result of the presence of two nitro­gen atoms acting together as an excellent leaving group, and an alkyl­idene group stabilized by different functionalities, the electrons are delocalized between three atoms and thus a positive and one negative charge theoretically allows by a disregard of the coordinating residuals and chemical conditions four different resonance structures to be gained in total. Therefore, the diazo compound can be regarded as both a nucleophilic and as an electrophilic reaction partner. By the use of this compound, a targeted synthesis of cyclo­propanes or rather hetero­cyclo­propanes, consisting of a transition metal, an electron-donor atom and a carbene carbon, is possible and has been reported several times in the literature (e.g. Nomura et al., 2011; Liu & Yan, 2015; Malisch et al., 1998; Strecker et al., 1991; Zhang et al., 2005, and references cited therein). An electrophilic reaction partner such as a transition metal establishes a nucleophilic attack of the diazo subunit and, according to the choice of the reaction conditions, the elimination of the nitro­gen leaving group is supported. Consequently, the alkyl­idene carbon atom is stabilized by coordination of an electron-accepting atom and a reactive carbene inter­mediate complex is formed. The existence of a nucleophilic reaction partner in the vicinity of the carbene atom results in the formation of a ring including an alkyl­idene bridging subunit. In summary, the reaction of a diazo compound with an electrophilic and additionally a nucleophilic reaction partner initiates a mechanism that can be described as a cheletropic-like process. Inspired by this reaction sequence, we have synthesized a three-membered heterocycle by the combination of an ethyl diazo­acetate and an iridium(III) PCP pincer carbodi­phospho­rane complex.

If the starting materials [CH(dppm)₂]Cl (Reitsamer et al., 2012) and [IrCl(cod)]₂ are mixed, a reaction sequence is initialized that consists of the following steps: Coordination of the iridium(I) atom, followed by deprotonation of the carbodi­phospho­rane carbon atom, the generation of a hydrido ligand caused by an oxidation of the iridium(I) atom and the formation of the [Ir{C(dppm)₂-κ³P,C,P`}ClH(MeCN)]Cl complex 1 (Schlapp-Hackl et al., 2018; Fig. 1). In summary, the iridium(III) transition metal is stabilized by the PCP pincer ligand system, and by a chlorido and a hydrido ligand and an aceto­nitrile solvent mol­ecule. The addition of ethyl diazo­acetate causes, via loss of the di­nitro­gen subunit, the formation of an Ir^III–carbene bond. As a result of the presence of the second free lone-electron pair at the carbodi­phospho­rane carbon atom, a cyclization and further the creation of an alkyl­idene bridge is accomplished. The formation of the three-membered Ir—C_CDP—C ring is accompanied by a surprising displacement of the hydrido ligand from a position perpendicular to the plane of the PCP pincer system to a meridional arrangement trans to the carbodi­phospho­rane carbon atom. Supported by the polar solvent mixture methanol/aceto­nitrile (v/v 5:1) an [Ir^III{C(CHCO₂Et)(dppm)₂-κ⁴P,C,C′,P′}H(MeCN)]Cl₂ precursor system (2) is generated in high yields (86%). Moreover, the preparation of complex 2 in a less polar solvent environment like chloro­form/aceto­nitrile or in a solvent mixture of methyl­ene chloride/aceto­nitrile (v/v 5:1) is not possible and qu­anti­tatively results in the substitution of one phosphine moiety of the carbodi­phospho­rane functionality against the carbene CHCO₂Et subunit. An [Ir{C(CHCO₂Et)(dppm)-κ²P,C}Cl(dppm)H]Cl complex 3 is generated, offering a phospho­rus ylide carbon backbone (Schlapp-Hackl et al., 2018). To a lesser extent (14% yield), this complex is additionally obtained as by-product by the production of complex 2. Heating of complex 2 in methanol/aceto­nitrile (v/v 5:1) to 333 K for 2 h benefits the ring-opening reaction of the PCCP pincer ligand system. Therefore, a reorganization of the ligand system is supported, resulting in the qu­anti­tative formation of complex 3. Furthermore, evaporation of the reaction mixture of complex 2 causes an exchange of the aceto­nitrile solvent ligand with a chloride counter-ion and the creation of the desired [Ir^III{C(CHCO₂Et)(dppm)₂-κ⁴P,C,C′,P′}ClH]Cl complex 4.

Figure 1 Scheme (Cambridge Soft, 2001) for the synthesis and crystallization of the title compounds 4–7.

The stucture of this irid­ium(III) PCCP complex was completely determined by NMR spectroscopy and X-ray crystallography, but up to now crystallization attempts of the inter­mediates, 1 and 2, were unsuccessful. With regard to a ruthenium PCP pincer complex, a related cyclo­addition was monitored (Zhang et al., 2005). Thereby, the ruthenium transition metal first stabilizes the phenyl­diazo­methane by coordination. After the elimination of the di­nitro­gen mol­ecule, the formation of the corresponding carbene complex and finally a carbon–carbon coupling reaction between the central carbon atom of the phenyl-based PCP ligand and the carbene was detected. As a consequence, the arene backbone of the PCP ligand system is transformed to an arenium moiety. Treatment of complex 4 with an additional equivalent amount of ethyl diazo­acetate causes an insertion reaction of the alkyl­idene to the iridium(III)–hydrido bond and the formation of the [Ir^III{C(CHCO₂Et)(dppm)₂-κ⁴P,C,C′,P′}(CH₂CO₂Et)Cl]Cl alkyl derivative 5. This reaction procedure is well known, and the mechanism of the inter­molecular insertion reaction has been clarified via an inter­mediate carbene complex (Cohen et al., 2003). Moreover, treatment of complexes 4 and 5 with hydro­chloric acid leads to a ligand substitution at the position trans to the central carbon atom of the PCP pincer ligand system with a chloride ion and to the formation of the [Ir^III{C(CHCO₂Et)(dppm)₂-κ⁴P,C,C′,P′}Cl₂]Cl complex 6. Besides, a replacement of the chlorido ligand of compound 5 by a carbonyl group is possible and results in the [Ir^III{C(CHCO₂Et)(dppm)₂-κ⁴P,C,C′,P′}(CH₂CO₂Et)(CO)]Cl₂ complex 7.

Here we report details of the syntheses and crystal structures of complexes 4–7.

2. Structural commentary

The asymmetric unit of compound 4, [Ir^III{C(CHCO₂Et)(dppm)₂-κ⁴P,C,C′,P′}ClH]Cl, comprises of one formula unit of 4 and additionally of 2.75 mol­ecules of methyl­ene chloride solvent mol­ecules. The central iridium(III) transition metal is surrounded in a distorted octa­hedral fashion by a PCCP pincer-like ligand system, and anionic chlorido and hydrido ligands (Fig. 2). The neutral [C(CHCO₂Et)(dppm)₂-κ⁴P,C,C′,P′] ligand coordinates the Ir^III metal in a tetra­dentate fashion via two P and two C atoms under formation of two five-membered, dissimilar chelate rings [C4—C1—P3 = 120.2 (3)°, C4—C1—P2 = 112.1 (3)°] and one three membered heterocycle. The PCP ligand exhibits a meridional arrangement with the hydrido ligand completing the equatorial plane trans to the C1 carbodi­phospho­rane atom. A cyclo­propane-like chelate ring is positioned nearly normal (84.21°) to the equatorial plane, and a chlorido ligand is positioned trans to the alkyl­idene carbon atom C4. The Ir—C1 [2.273 (4) Å] and Ir—C4 [2.072 (5) Å] distances differ significantly and consequently these values substanti­ate a strengthened inter­action between the iridium(III) metal and the alkyl­idene carbon atom. The C1—C4 separation [1.515 (6) Å] is slightly shorter in comparison to a typical C—C single bond but, in general, very close to that of cyclo­propanes. However, in comparison with a cyclo­propane mol­ecule the C4—Ir1—C1 [40.5 (2)°], C4—C1—Ir1 [62.6 (2)°] and C1—C4—Ir1 [76.9 (3)°] angles emphasise a significant distortion of the synthesized three-membered heterocycle. All mentioned geometric features of this strained Ir—C1—C4 metallacycle can be associated with the structural results of the Ru—C—C triangle reported by Zhang et al. (2005). Furthermore, the three-membered ring causes a distortion of the octa­hedral coordination geometry (Table 1). The P1—Ir1—P4 [178.4 (1)°] atoms are less affected and show only a slight deviation from linearity. Though, the tetra­hedral environment of the carbodi­phospho­rane C1 atom is strongly influenced and thus distorted, which is reflected by a P3—C1—P2 angle of 124.2 (3)°. Overall, the transition metal and its ligand system present a cationic complex balanced by one chloride.

Figure 2 Mol­ecular structure of the complex cation in 4 and the counter-anion. Displacement ellipsoids are drawn at the 30% probability level. For clarity, only the ipso carbon atoms of the phenyl groups are presented and the solvent mol­ecules are omitted.

The asymmetric unit of compound 5, [Ir^III{C(CHCO₂Et)(dppm)₂-κ⁴P,C,C′,P′}(CH₂CO₂Et)Cl]Cl, is defined by one complex 5, one half-occupied water mol­ecule and one disordered methanol solvent mol­ecule. In comparison with the structural features discussed in detail for compound 4, significant differences pertain only to the equatorial position trans to C1. Here the hydrido ligand in 4 is exchanged by an ethyl acetate unit (Fig. 3).

Figure 3 Mol­ecular structure of the complex cation in 5 and the counter-anion. Displacement ellipsoids are drawn at the 30% probability level. For clarity, only the ipso carbon atoms of the phenyl groups are presented and the solvent mol­ecules are omitted.

The replacement of the hydrido ligand of compound 4 by a chlorido ligand led to formation of 6, [Ir^III{C(CHCO₂Et)(dppm)₂-κ⁴P,C,C′,P′}Cl₂]Cl. In its crystalline form, besides one formula unit of 6, one solvent mol­ecule of MeOH and two water mol­ecules in total are present in the asymmetric unit. Overall, this PCCP derivative shows very similar structural characteristics (Fig. 4) to complex 4.

Figure 4 Mol­ecular structure of the complex cation in 6 and the counter-anion. Displacement ellipsoids are drawn at the 30% probability level. For clarity, only the ipso carbon atoms of the phenyl groups are presented and the solvent mol­ecules are omitted.

Finally, an elimination of the chlorido ligand of complex 5 and its replacement by a carbonyl ligand results in compound 7, [Ir^III{C(CHCO₂Et)(dppm)₂-κ⁴P,C,C′,P′}(CH₂CO₂Et)(CO)]Cl₂ (Fig. 5). The asymmetric unit comprises one complex mol­ecule of 7 and additionally of two methyl­ene chloride solvent mol­ecules and 1.5 mol­ecules of water. In comparison with complex 5, the structural features have not changed dramatically, with some slight variations for bond lengths and angles (Table 1).

Figure 5 Mol­ecular structure of the complex cation in 7 and the two counter-ions. Displacement ellipsoids are drawn at the 30% probability level. For clarity, only the ipso carbon atoms of the phenyl groups are presented and the solvent mol­ecules are omitted.

3. Supra­molecular features

In all crystal structures, the complex cations and counter-ions are packed in a way that leaves voids for various types of solvent mol­ecules. Weak non-classical hydrogen-bonding inter­actions are observed between complex cations, chloride counter-ions and solvent mol­ecules. Numerical details of these inter­actions are given in Tables 2–5, and discussed briefly below.

In the structure of 4, there are weak C—H⋯Cl inter­actions between the chloride counter-ion and the methyl­ene groups of the PCP pincer ligand system [Cl2⋯H2B = 2.58 Å, H3B⋯Cl2(x − 1, y, z) = 2.83 Å] exhibiting distances shorter than the sum of the van der Waals radii (Table 2, Fig. 6). Such C—H⋯X inter­actions are a common feature of complexes containing dppm or related ligands (Jones & Ahrens, 1998).

Figure 6 A view along the c axis of the crystal packing of compound 4. Only the H atoms involved in the most significant inter­molecular inter­actions (Table 2) are displayed and the intra­molecular inter­action is omitted.

Moreover, compound 5 shows C—H⋯O and C—H⋯Cl inter­actions (Table 3) between the methyl­ene groups of the dppm moieties and the solvent mol­ecules and additionally the counter-ion, forming short contacts of 2.22 Å [H2A⋯O5 (x, y − 1, z)], 2.91 Å (H3A⋯Cl2) and 2.40 Å (H3B⋯O1) (Fig. 7).

Figure 7 A view along the a axis of the crystal packing of compound 5. Only the H atoms involved in the most significant inter­molecular inter­actions (Table 3) are presented and the intra­molecular inter­actions are omitted. One phenyl group and the solvent mol­ecules show positional disorder.

In the structure of 6, the methyl­ene groups of the PCP unit and the chloride counter-ion and the solvent mol­ecules form C—H⋯O and C—H⋯Cl inter­actions (Table 4), exhibiting distances of 2.45 Å [H2B⋯O5(x, y − 1, z)], 2.66 Å (H3B⋯Cl3) and 2.40 Å [H6A⋯O3 (−x + 1, −y, −z + 2)] (Fig. 8).

Figure 8 A view along the a axis of the crystal packing of compound 6. Only the H atoms involved in the most significant inter­molecular inter­actions (Table 4) are presented and the intra­molecular inter­actions are omitted.

In compound 7, the chloride counter-ions inter­act with both the PCP pincer ligand system and the solvent mol­ecules. The solvent mol­ecules also show inter­actions with the iridium complex (Table 5, Fig. 9).

Figure 9 A view along the a axis of the crystal packing of compound 7. Only the H atoms involved in the most significant inter­molecular inter­actions (Table 5) are presented and the intra­molecular inter­actions are omitted. The solvent mol­ecules are disordered.

4. Synthesis and crystallization

Each reaction step was carried out under an atmosphere of nitro­gen by the use of standard Schlenk techniques. All starting materials and solvents were obtained from commercial suppliers, excluding the compound [CH(dppm)₂]Cl that was prepared by a previously reported procedure (Reitsamer et al., 2012). ¹H-, ¹³C- and ³¹P-NMR spectra were recorded on a Bruker DPX 300 NMR spectrometer and were referenced against the ¹³C/¹H peaks of deuterated solvents chloro­form and methanol or an external 85% H₃PO₄ standard, respectively. For the following assignment of the NMR data, atoms are labelled as in Figs. 2, 3, 4, 5.

Synthesis of [Ir^III{C(CHCO₂Et)(dppm)₂-κ⁴P,C,C′,P′}ClH]Cl·2.75CH₂Cl₂ (4): A mixture of [CH(dppm)₂]Cl (0.0250 mmol, 20.4 mg) and [IrCl(cod)]₂ (0.0125 mmol, 8.4 mg) was solved in 0.1 ml of MeCN. After a reaction time of one minute, a solution of ethyl diazo­acetate (0.0250 mmol, 2.85 mg) in MeOH (0.5 ml) was added. 10 min later, a deep yellow liquid was obtained. The volatiles were removed and the remaining solid was dissolved in methyl­ene chloride (0.6 ml), leading to complex 4 in high yield (0.0250 mmol, 28.3 mg). Single crystals of complex 4 were grown from a solvent mixture of n-hexane (1.2 ml) and CH₂Cl₂ (0.2 ml). ³¹P {¹H} NMR (CHCl₃): δ = 18.8 (ddd, P1, ²J_P1P2 = 16.9 Hz, ⁴J_P1P3 = 16.6 Hz, ²J_P1P4 = 399.2 Hz), 38.1 (ddd, P2, ²J_P2P3 = 38.3 Hz, ⁴J_P2P4 = 16.9 Hz), 34.7 (ddd, P3, ²J_P3P4 = 29.0 Hz), 10.7 (ddd, P4) ppm; ¹H NMR (CDCl₃/MeOH, 5:1): δ = −15.2 (ddddd, hydride, ³J_P2H = 5.5 Hz, ³J_P3H = 5.5 Hz, ²J_P1H = 13.1 Hz, ²J_P4H = 13.1 Hz, ²J_C1H = 14.3 Hz) ppm; ¹³C {¹H} NMR (CDCl₃): δ = 3.6 (dddd, C1, ¹J_C1P2 = 63.5 Hz, ²J_C1P3 = 74.6 Hz, ²J_C1P1 = 3.9 Hz, ²J_C1P4 = 3.9 Hz) ppm.

Synthesis of [Ir^III{C(CHCO₂Et)(dppm)₂-κ⁴P,C,C′,P′}(CH₂CO₂Et)Cl]Cl·CH₃OH·0.5 H₂O (5): Ethyl diazo­acetate (0.116 mmol, 13.2 mg) was added to a solution of complex 4 (0.0250 mmol, 28.3 mg) in CH₂Cl₂ (0.6 ml), and the reaction mixture was stirred for 30 min. Complex 5 (0.0250 mmol, 30.7 mg) was formed qu­anti­tatively. Single crystals were obtained via slow evaporation of a 1:1methyl­ene chloride/methanol mixture. ³¹P {¹H} NMR (CHCl₃): δ = 0.3 (ddd, P1, ²J_P1P2 = 24.4 Hz, ⁴J_P1P3 = 10.6 Hz, ²J_P1P4 = 436.4 Hz), 40.6 (dddd, P2, ²J_P2P3 = 35.1 Hz, ⁴J_P2P4 = 15.3 Hz), 36.4 (dddd, P3, ²J_P3P4 = 15.9 Hz), −4.4 (ddd, P4) ppm; ¹³C {¹H} NMR (CDCl₃): δ = 3.1 (dddd, C1, ¹J_C1P2 = 68.8 Hz, ¹J_C1P3 = 55.6 Hz, ²J_C1P1 = 3.5 Hz, ²J_C1P4 = 3.5 Hz) ppm.

Synthesis of [Ir^III{C(CHCO₂Et)(dppm)₂-κ⁴P,C,C′,P′}Cl₂]Cl·CH₃OH·2H₂O (6): A solution of complex 4 (0.0250 mmol, 28.3 mg) in CH₂Cl₂ (0.6 ml) was treated with hydro­chloric acid (77.0 µl, 37%, 0.925 mmol) and stirred vigorously for approximately 10 min. The organic phase was separated and washed with water (0.5 ml) three times in total. Complex 6 (0.0250 mmol, 29.1 mg) was formed almost qu­anti­tatively. Yellow single crystals were generated by slow evaporation of a 1:1 solvent mixture of MeCN and MeOH. ³¹P {¹H} NMR (CHCl₃): δ = −6.1 (ddd, P1, ²J_P1P2 = 19.9 Hz, ⁴J_P1P3 = 19.8 Hz, ²J_P1P4 = 452.1 Hz), 46.9 (ddd, P2, ²J_P2P3 = 38.3 Hz, ⁴J_P2P4 = 30.6 Hz), 45.8 (ddd, P3, ²J_P3P4 = 19.8 Hz), −10.3 (ddd, P4) ppm; ¹³C {¹H} NMR (CDCl₃): δ = 3.8 (dd, C1, ¹J_C1P2 = 50.2 Hz, ¹J_C1P3 = 50.2 Hz) ppm.

Synthesis of [Ir^III{C(CHCO₂Et)(dppm)₂-κ⁴P,C,C′,P′}(CH₂CO₂Et)(CO)]Cl₂·2CH₂Cl₂·1.5H₂O (7): A solution of complex 5 (0.025 mmol, 29.1 mg) in CH₂Cl₂ was placed under an atmosphere of CO. After a reaction time of 1 h, complex 7 had formed qu­anti­tatively (0.0250 mmol, 31.1 mg). Single crystals were grown from a solution of methyl­ene chloride, covered with a small amount of ethyl acetate. ³¹P {¹H} NMR (CH₂Cl₂): δ = −6.5 (ddd, P1, ²J_P1P2 = 14.2 Hz, ⁴J_P1P3 = 9.5 Hz, ²J_P1P4 = 339.8 Hz), 41.2 (ddd, P2, ²J_P2P3 = 27.7 Hz, ⁴J_P2P4 = 18.4 Hz), 39.7 (ddd, P3, ²J_P3P4 = 12.3 Hz), −16.4 (ddd, P4) ppm; ¹³C {¹H} NMR (CD₂Cl₂): δ = 16.1 (ddd, C1, ¹J_C1P2 = 59.8 Hz, ¹J_C1P3 = 49.3 Hz, ²J_C1P4 = 2.7 Hz, ²J_C1C12 = 1.5 Hz), 172.8 (ddd, C12, ²J_C12P1 = 8.6 Hz, ²J_C12P4 = 8.6 Hz) ppm.

5. Refinement

Crystal data, data collection and structure refinement details are summarized in Table 6. Diffraction data for all crystals were measured by using multiple scans to increase the number of redundant reflections. We found the data of sufficient quality to proceed without semi-empirical absorption methods.

Table 6 Experimental details   4 5 6 7 Crystal data Chemical formula [IrClH(C55H50O2P4)]Cl·2.75CH2Cl2 [Ir(C4H7O2)Cl(C55H50O2P4)]Cl·CH4O·0.5H2O [IrCl2(C55H50O2P4)]Cl·CH4O·2H2O [Ir(C4H7O2)(C55H50O2P4)(CO)]Cl2·2CH2Cl2·1.5H2O Mr 1364.48 1258.07 1233.45 1441.91 Crystal system, space group Monoclinic, P21/n Triclinic, P Triclinic, P Triclinic, P Temperature (K) 233 233 233 233 a, b, c (Å) 12.4425 (2), 22.4020 (3), 22.5393 (3) 12.4253 (3), 13.7081 (4), 17.6780 (6) 11.2371 (2), 12.9144 (2), 19.2371 (3) 11.7326 (2), 13.8815 (2), 22.2615 (3) α, β, γ (°) 90, 94.826 (1), 90 93.152 (2), 97.960 (2), 103.771 (2) 89.439 (1), 77.863 (1), 83.114 (1) 75.477 (1), 86.508 (1), 65.212 (1) V (Å3) 6260.26 (16) 2884.18 (15) 2709.27 (8) 3182.38 (9) Z 4 2 2 2 Radiation type Mo Kα Mo Kα Mo Kα Mo Kα μ (mm−1) 2.59 2.57 2.78 2.50 Crystal size (mm) 0.11 × 0.08 × 0.05 0.15 × 0.05 × 0.02 0.11 × 0.05 × 0.03 0.31 × 0.23 × 0.19   Data collection Diffractometer Nonius KappaCCD Nonius KappaCCD Nonius KappaCCD Nonius KappaCCD No. of measured, independent and observed [I > 2σ(I)] reflections 39699, 11006, 8888 13821, 7453, 6326 17984, 9526, 8083 23329, 12496, 11695 Rint 0.045 0.037 0.035 0.024 θmax (°) 25.0 22.4 25.0 26.0   Refinement R[F2 > 2σ(F2)], wR(F2), S 0.040, 0.112, 1.04 0.044, 0.106, 1.07 0.034, 0.073, 1.05 0.028, 0.070, 1.05 No. of reflections 11006 7453 9526 12496 No. of parameters 711 674 626 751 No. of restraints 2 1 1 3 H-atom treatment H atoms treated by a mixture of independent and constrained refinement H atoms treated by a mixture of independent and constrained refinement H atoms treated by a mixture of independent and constrained refinement H atoms treated by a mixture of independent and constrained refinement Δρmax, Δρmin (e Å−3) 1.03, −0.86 0.90, −0.96 0.75, −1.01 0.97, −1.29 Computer programs: COLLECT (Nonius, 1999), DENZO and SCALEPACK (Otwinowski & Minor, 1997), XP in SHELXTL and SHELXS97 (Sheldrick, 2008), SHELXL2014/7 (Sheldrick, 2015), (Sheldrick, 2008), publCIF (Westrip, 2010) and CHEMDRAW (Cambridge Soft, 2001).

Unless noted otherwise, H atoms in the four structures were placed geometrically and refined in the riding-model approximation with U_iso(H) = 1.2U_eq(C) for phenyl and methyl­ene H atoms and 1.5U_eq(C) for methyl H atoms.

For compound 4, the two hydrogen atoms bound to the central Ir1 atom and the C4 atom of the eth­oxy­oxoethanyl­idene moiety were discernible from a difference-Fourier map. They were refined with bond-length restraints of 0.96 Å (C4) and 1.60 Å (Ir1) and with individual U_iso values. Three of the four methyl­ene chloride solvent mol­ecules are disordered. One solvent mol­ecule (C9, Cl3, Cl4) shows half-occupation, one (C12, Cl9, Cl10) is disordered around an inversion centre (occupancy 0.25) and for one (C11, Cl7, Cl8) the Cl atoms show a positional disorder over two sites (ratio 0.7:0.3). All H atoms of the solvent mol­ecules were omitted from the final model.

The scattering power of the crystal of compound 5 was poor. Hence, it was possible to collect reflections only up to 45°/2θ. The H atom attached to the C4 position was treated as described above. The methanol (C13, O6) and water (O7) solvent mol­ecules are disordered around an inversion centre and were refined with half-occupation. H atoms of the disordered solvent mol­ecules were omitted from the model. Furthermore, one phenyl group shows a 1:1 positional disorder and was refined over two sets of sites (C401–C406; C41A–C46A). All atoms of the disordered phenyl ring were refined isotropically.

In compounds 6 and 7, the H atom attached to the C4 position was treated as described above. For 6, localization of the H atoms of the methanol and water solvent mol­ecules was not possible and hence they were omitted from the model. For 7, H atoms of water mol­ecule O6 were located from a difference-Fourier map and refined with bond-length restraints of 0.84 Å. The O7 atom of the other water mol­ecule was treated as being half-occupied, and its H atoms were omitted from the model. One methyl­ene chloride solvent mol­ecule (C14, Cl5, Cl6) was refined over two sets of sites (ratio 0.65:0.35).