1. Chemical context

Based on a great number of investigations of iridium complexes in organic synthesis (Oro & Claver, 2009), on the large variety of metal–pincer ligand inter­actions and reactivities (Morales-Morales & Jensen, 2007; Choi et al., 2011), the catalytic and stoichiometric organometallic chemistry of iridium PCP pincer complexes attracted our attention.

Up to now, diverse PCP pincer systems have been generated and these systems are, in general, classified according to the charge of the central carbon atom. Both an anionic sp² or sp³ hybridization of the central carbon atom is possible (Table 1) and the charge arises from the metallation of the pertinent C—H functionalities of the non-coordinated ligand subunits. Furthermore, neutral PCP pincer ligands containing a divalent carbon(II) donor atom, for instance an alkyl­idene carbene or a NHC, are well known (Table 1; Crocker et al., 1982). Moreover, PCP pincer complexes based on tropylium backbones have been reported. The cationic central carbon atom is part of a seven-membered six-electron arene fragment and because of the C—C bond lengths, designation as a cyclo­hepta­trienyl­idene carbene is allowed (Table 1).

Table 1 Comparative Ir—CPCP and Ir—CCO bond lengths (Å) of different [Ir(CO)ClH(PCP)] complexes PCP ligand or backbone (charges are omitted) PCP central carbon atom Ir—CCO Ir—CPCP Reference C6H3-1,3-[OPR2]2 sp2 2.045 (3) 1.949 (4) Goldberg et al. (2015) C6H3-1,3-[OPR2]2 sp2 2.057 (3) 1.913 (4) Goldberg et al. (2015) C6H3-1,3-[OPR2]2 sp2 2.071 (2) 1.921 (3) Goldberg et al. (2015) C(NCH2PR2)2C10H6 NHC 2.078 (4) 1.904 (5) Hill & McQueen (2012) benzotropylium alkyl­idene 2.082 1.929 Leis et al. (2014) tropylium alkyl­idene 2.093 (5) 1.916 (5) Winter et al. (2005) C6H3-1,3-[P(CF3)2]2 sp2 2.103 (2) 1.952 (3) Adams et al. (2011) C3H3-1,2-[OPR2]2 sp3 2.126 (8) 1.880 (7) Ruhland & Herdtweck (2005) CH(NCH2PR2)2C10H6 sp3 2.141 (5) 1.904 (6) Hill & McQueen (2012) C(dppm)2 CDP 2.157 (5) 1.891 (6) this work cyclo­hex­yl sp3 2.159 (4) 1.909 (5) Jonasson et al. (2015) trypticene sp3 2.163 (2) 1.895 (2) Azerraf & Gelman (2009) cyclo­hex­yl sp3 2.165 (5) 1.906 (6) Mayer et al. (1993) trypticene sp3 2.193(3 1.898 (3) Azerraf & Gelman (2009) CH(dppm)2 protonated CDP 2.207 (3) 1.874 (4) this work cyclo­hepta­trien­yl sp3 2.25 (2) 1.78 (1) Nemeh et al. (1998)

Our focus is on the creation of new iridium complexes containing a PCP ligand system with a neutral or a cationic central carbon atom, respectively. The central carbon is part of a carbodi­phospho­rane (CDP) functionality and can be described as a naked carbon atom or as a divalent carbon(0) atom in an excited singlet (1D) state stabilized by two tertiary phosphines via donor–acceptor inter­actions. Consequently, this central atom disposes of two lone-electron pairs and is able to inter­act with one or two Lewis acids (Petz & Frenking, 2010).

The protonated CDP ligand system [CH(dppm)₂]Cl enters an oxidative addition reaction with Vaska's compound [Ir^I(CO)Cl(PPh₃)₂], forming the iridium PCP pincer CDP complex [Ir^III(CO)(C(dppm)₂-κ³P,C,P′)ClH]Cl (1) (see reaction scheme). During this reaction sequence, the central carbon atom is deprotonated, becomes neutral and coordin­ates the iridium transition metal. Treatment of complex 1 with hydro­chloric acid leads to the protonation of the central carbon atom and consequently to the formation of the conjugate CH acid of 1, the [Ir(CO)(CH(dppm)₂-κ³P,C,P′)ClH]Cl₂ complex 2 (see reaction scheme). Relative to the hydrido ligand at the iridium transition metal, the additionally attached proton adopts a syn- or anti-periplanar conformation. In solution, the existence of both isomers can be demonstrated by the use of NMR spectroscopy. However, the examination of several crystals revealed only the anti-periplanar configuration of complex 2. Whether this is incidental or the crystallization is accompanied by the isomerization of the syn-periplanar to the anti-periplanar conformation is unclear.

2. Structural commentary

Complex 1 (Fig. 1) crystallizes in the monoclinic space group P2₁/n and the asymmetric unit consists of one formula unit of 1 and three mol­ecules of CH₂Cl₂. The structure can be divided into two parts, the [Ir^III(CO)(C(dppm)₂-κ³P,C,P′)ClH]⁺ monocation and the chloride counter-ion. The iridium transition metal centre exhibits an octa­hedral ligand system, formed by a meridional arranged C(dppm)₂, relative to the C1 atom, a trans-coordinated carbonyl unit, and a chlorido and hydrido ligand located perpendicular to the meridional plane or more precisely trans to each other. The P1—Ir1—P4 angle of 170.69 (5)° indicates a small deviation from the octa­hedral geometry and this value is larger compared to many related Iridium PCP pincer complexes. The environment of the CDP carbon atom C1 is strictly planar (sum of angles at C1 = 360°; Table 2) and the C1—P2 and C1—P3 bond lengths are 1.697 (5) and 1.711 (5) Å, respectively. Not only the geometry, but also the bond lengths are characteristic for a carbodi­phospho­rane atom, which inter­acts with one Lewis acid (Petz & Frenking, 2010). In general, bond lengths are directly connected with the valence-bond structure of a carbon atom and an increasing of the valence state causes a significant expansion of the bond gaps [Csp² < C(carbene) < Csp³]. Consequently, the Ir1—C1 separation of 2.157 (5) Å indicates an sp³ hybridization of the carbodiphosphorane carbon atom, which is substantiated by the data collected in Table 1. Additionally, inter­actions (Table 3) between the chloride counter-ion and the methyl­ene groups of the PCP pincer ligand system can be detected and the bond lengths of about 2.60 Å [Cl2⋯H2B(1 + x, y, z)] and 2.62 Å [Cl2⋯H3B(1 + x, y, z)] illustrate the location within the van der Waals radii. These C—H⋯X inter­actions are a common feature of complexes containing dppm or related ligands (Jones & Ahrens, 1998). Moreover, the chloride counter-ion inter­acts with the hydrogen atoms of the CH₂Cl₂ mol­ecules as well, forming distances of about 2.59 Å [Cl2⋯H5B( + x,  − y,  + z)] and 2.47 Å [Cl2⋯H6B(− − x,  + y,  − z)].

Table 3 Hydrogen-bond geometry (Å, °) for complex 1 D—H⋯A D—H H⋯A D⋯A D—H⋯A C2—H2B⋯Cl2 0.98 2.60 3.534 (5) 160 C3—H3B⋯Cl2i 0.98 2.62 3.544 (5) 157 C5—H5B⋯Cl2ii 0.98 2.59 3.541 (10) 165 C6—H6B⋯Cl2iii 0.98 2.47 3.436 (10) 169 C7—H7A⋯Cl1iv 0.98 2.50 3.447 (15) 163 C105—H105⋯Cl1v 0.94 2.72 3.573 (8) 151 C312—H312⋯Cl2i 0.94 2.78 3.690 (6) 163 Symmetry codes: (i) x+1, y, z; (ii) ; (iii) ; (iv) ; (v) -x, -y, -z+2.

Figure 1 Structure of complex 1 with displacement ellipsoids drawn at the 30% probability level. Solvent residues are omitted.

The asymmetric unit of 2 comprises two [Ir^III(CO)(CH(dppm)₂-κ³P,C,P′)ClH]Cl₂ complex mol­ecules (Fig. 2), four mol­ecules of HCl and eleven mol­ecules of water in total. Both complex mol­ecules are distinctly asymmetric in the solid state. As a result of the threefold coordination of the transition metal by the PCP pincer ligand system, two five-membered metallacycles are formed, each adopting an approximately envelope conformation. One methyl­ene group (C3) and one phospho­rus atom (P2) are positioned at the flap positions above the plane generated by the C1–C2–P1–Ir1 and C1–Ir1–P3–P4 atoms. Complex 2 crystallizes in the monoclinic space group P2₁/n and the complex mol­ecule can be described as one [Ir^III(CO)(CH(dppm)₂-κ³P,C,P′)ClH]²⁺ dication stabilized by two chloride counter-ions. Overall, complex 2 represents the conjugate CH acid of the [Ir^III(CO)(C(dppm)₂-κ³P,C,P′)ClH]Cl complex (1). The carbodi­phospho­rane carbon atom additionally coordinates a second Lewis acid, the proton H1, which adopts an anti-periplanar conformation relative to the hydrido ligand H11. As a consequence, atom C1 forms a distorted tetra­hedron with the directly coordinated atoms (sum of angles = 344.3°). In comparison with complex 1, the values of the angles P2—C1–Ir1 and P3—C1—Ir1 are significantly reduced, whereas the P2—C1—P3 angles differs to a lesser extent (Table 2). The coordination of a second Lewis acid causes a lengthening of the C1—P distances by about 0.098 Å, resulting in bond lengths in the range of P—C single bonds. Moreover, the Ir1—C1 distance [2.207 (3) Å] is markedly longer compared to that of the conjugate base 1 [2.157 (5) Å], as has also been observed in other carbodi­phospho­rane complexes (Petz et al., 2009; Reitsamer et al., 2012; Tonner et al., 2006). Furthermore, the protonation of the C1 atom leads to a decrease of the trans influence of the carbodi­phospho­rane carbon donor atom, confirmed by an shortening of the Ir—CO distance and an increasing of the carbonyl bond gap. Besides, C—H⋯O and C—H⋯Cl interactions (Table 4) between the methylene groups of the dppm moieties and the water or HCl molecules can be detected, causing for example separations in the range of 2.61 Å [H2A⋯O4(1 − x, 1 − y, 1 − z)], 2.89 Å [H2B⋯Cl7(x − , −y + , z + )], 2.51 Å [H3A⋯Cl8(x, 1 + y, z)] and 2.57 Å [H3B⋯Cl5(x, 1 + y, z)].

Table 4 Hydrogen-bond geometry (Å, °) for complex 2 D—H⋯A D—H H⋯A D⋯A D—H⋯A C1—H1⋯Cl1 0.96 (3) 2.82 (3) 3.252 (3) 109 (2) C3—H3A⋯Cl8i 0.98 2.51 3.466 (4) 164 C3—H3B⋯Cl5i 0.98 2.57 3.493 (4) 158 C6—H6A⋯O8ii 0.98 2.59 3.431 (5) 144 C6—H6B⋯Cl9ii 0.98 2.82 3.746 (4) 158 C7—H7A⋯Cl1Aiii 0.98 2.73 3.614 (6) 150 C7—H7B⋯Cl4iii 0.98 2.60 3.518 (4) 157 C206—H206⋯Cl7iii 0.94 2.79 3.719 (4) 172 C310—H310⋯Cl4ii 0.94 2.83 3.714 (4) 158 C602—H602⋯Cl9ii 0.94 2.62 3.557 (4) 179 C704—H704⋯Cl1iv 0.94 2.82 3.534 (6) 134 C708—H708⋯Cl2 0.94 2.80 3.503 (4) 132 C710—H710⋯Cl5v 0.94 2.72 3.614 (4) 160 C712—H712⋯Cl10iii 0.94 2.81 3.734 (6) 167 Symmetry codes: (i) x, y+1, z; (ii) ; (iii) ; (iv) -x, -y+1, -z+1; (v) -x+1, -y, -z+1.

Figure 2 Structure of one of the two independent molecules of complex 2 with displacement ellipsoids drawn at the 30% probability level. Solvent residues are omitted.

In 1, there are inter­actions (Table 3) between the chloride counter-ion and the methyl­ene groups of the PCP pincer ligand system [Cl2⋯H2B = 2.60 Å, H3B⋯Cl2(1 + x, y, z) = 2.62 Å] with distances shorter than the sum of the van der Waals radii. Such C—H⋯X inter­actions are a common feature of complexes containing dppm or related ligands (Jones & Ahrens, 1998). Moreover, the chloride counter-ion also inter­acts with the hydrogen atoms of the CH₂Cl₂ mol­ecules [H5B⋯Cl2( + x,  − y,  + z) = 2.59 Å and H5B⋯Cl2(− − x,  + y,  − z) = 2.47 Å].

In 2, C—H⋯O and C—H⋯Cl inter­actions (Table 4) occur between the methyl­ene groups of the dppm moieties and the water or HCl mol­ecules and there are short contacts of 2.61 Å [H2A⋯O4(1 − x, 1 − y, 1 − z)], 2.89 Å [H2B⋯Cl7(x − , −y + , z + )], 2.51 Å [H3A⋯Cl8(x, 1 + y, z)] and 2.57 Å [H3B⋯Cl5(x, 1 + y, z)]. A network of different inter­actions occurs between the two independent complex mol­ecules. The water and hydro­chloric acid solvent mol­ecules form hydrogen bonds with the chloride ligands or counter-ions and the hydrogen atoms of the complex mol­ecules, respectively.

3. Synthesis and crystallization

All preparations were carried out under an inert atmosphere (N₂) using standard Schlenk techniques. The ¹H, ¹³C and ³¹P NMR spectra were recorded on a Bruker DPX 300 NMR spectrometer and were referenced against the ¹³C/¹H solvent peaks of the solvents chloro­form, methanol or the external 85% H₃PO₄ standard, respectively. The phospho­rus atoms in the NMR data are labelled as in Figs. 1 and 2.

Synthesis of [Ir(CO)(C(dppm)₂-κ³P,C,P′)ClH]Cl (1): A mixture of 19.5 mg of Vaska's complex (0.025 mmol), 20.4 mg of [CH(dppm)₂]Cl (0.025 mmol) (Reitsamer et al., 2012) and CHCl₃ (0.6 ml) was stirred at ambient temperature for 15 min. The solvent was evaporated in vacuo and the residue was digested with a mixture of CH₂Cl₂ (0.1 ml) and ethyl acetate (0.7 ml). The solid was separated and washed twice with ethyl acetate (0.6 ml). Single crystals were grown by slow evaporation of a solution in CH₂Cl₂. ³¹P {¹H} NMR (CHCl₃): δ 31.9 (P2/P3, N = 71), δ 8.2 (P1/P4); ¹³C {¹H} NMR (CDCl₃): δ −4.4 (C1, ¹J_P2/P3C1 = 86, ¹J_P1/P4C1 = 6, ¹J_C1H(11) = 4); ¹H NMR (CDCl₃): δ −16.7 (H11, ¹J_P1/P4H11 = 10).

Synthesis of [Ir(CO)(CH(dppm)₂-κ³P,C,P′)ClH]Cl₂ (2): 19.5 mg of Vaska's complex (0.025 mmol) and 20.4 mg of [CH(dppm)₂]Cl (0.025 mmol) (Reitsamer et al., 2012) were solved in CHCl₃ (0.6 ml). The mixture was stirred at ambient temperature for 15 min. After addition of 0.1 ml of hydro­chloric acid (10 mol L⁻¹), the product crystallized upon standing for a day. ³¹P {¹H} NMR (CHCl₃/MeOH): δ 45.3 (P2/P3, N = 61), δ 1.7 (P1/P4); ¹³C {¹H} NMR (CDCl₃): δ 9.1 (C1, ¹J_P2/P3C1) = 38, ¹J_C1H1 = 122); ¹H NMR (CDCl₃/MeOH): δ −18.9 (H11, ¹J_P1/P4H11 = 11).

4. Refinement

Crystal data, data collection and structure refinement details are summarized in Table 5. Refinement of complex 1 resulted in the location of the hydride hydrogen atom. The bond length was restrained to a distance of 1.6 Å and a fixed isotropic displacement parameter of 1.5U_eq of iridium was applied. The hydrido ligand of complex 2 was also detected and refined isotropically without the use of bond restraints. Furthermore, the proton of the CDP carbon atom was spotted and refined with bond restraints of 0.98 Å. The hydrogen atoms of the water and solvent mol­ecules could only be partially detected and were omitted. A determination of a 1:1 positional disorder of one water mol­ecule (O4 and O4A) and one HCl or chloride (Cl10 and Cl1A) was possible. Eight chloride positions can be detected, which are occupied by a total of four chlorides and four hydro­chloric acid units. The hydrogen-atom positions of the phenyl subunits and methyl­ene groups were refined with calculated positions (C—H = 0.94 and 0.98 Å) using a riding model with U_iso(H) = 1.2U_eq(C).

Table 5 Experimental details   complex 1 complex 2 Crystal data Chemical formula [IrClH(CO)(C51H44P4)]Cl·3CH2Cl2 [IrClH(C51H44P4)(CO)]Cl2·2HCl·5.5H2O Mr 1327.64 1281.32 Crystal system, space group Monoclinic, P21/n Monoclinic, P21/n Temperature (K) 233 233 a, b, c (Å) 12.3477 (2), 24.7472 (5), 19.0123 (3) 19.7138 (2), 22.7327 (2), 25.3120 (3) β (°) 91.700 (1) 98.781 (1) V (Å3) 5807.05 (18) 11210.6 (2) Z 4 8 Radiation type Mo Kα Mo Kα μ (mm−1) 2.82 2.78 Crystal size (mm) 0.3 × 0.15 × 0.05 0.3 × 0.2 × 0.06   Data collection Diffractometer Nonius KappaCCD Nonius KappaCCD No. of measured, independent and observed [I > 2σ(I)] reflections 33007, 10203, 8088 68943, 22078, 17290 Rint 0.061 0.037   Refinement R[F2 > 2σ(F2)], wR(F2), S 0.043, 0.098, 1.06 0.033, 0.088, 1.04 No. of reflections 10203 22078 No. of parameters 625 1268 No. of restraints 1 2 H-atom treatment H-atom parameters constrained H-atom parameters constrained       Δρmax, Δρmin (e Å−3) 1.68, −0.91 2.03, −0.99 Computer programs: COLLECT Nonius, 1999, DENZO and SCALEPACK (Otwinowski & Minor, 1997), SHELXS97 and SHELXL97 (Sheldrick, 2008) and ChemDraw (Cambridge Soft, 2001).

The two complex mol­ecules of 2 are related to each other by the presence of a pseudo-symmetry centre. A halving of the c axis and consequently the changing of the monoclinic setting from P2₁/n to P2₁/c allows the consideration of one formula unit of 2. A closer observation of the sections of the reciprocal lattice along c* (l = 2n + 1) at different values of l results in the presence of frequent weak reflections. Consequently, an inter­pretation of this system as three-dimensional network between two complex mol­ecules, four hydro­chloric acid units and eleven water mol­ecules allows the involvement of these weak, but clearly existing reflections, and establishes the possibility of the distinction of the chloride and oxygen positions.