1. Chemical context

A divalent carbon(0) atom in an excited singlet (¹D) state, which may act as an electron-donor atom towards one or two Lewis acids, opens up a wide range of functionalities and chemical properties (Petz & Frenking, 2010). We decided to investigate these intriguing properties in detail and to explore this unusual donor species, generally known as a carbodi­phospho­rane (CDP) carbon atom, in combination with the transition metal iridium. We had earlier designed a new and innovative PCP pincer ligand system, which allows the stabil­ization of a carbodi­phospho­rane atom by two dppm subunits or, more precisely, by two tertiary phosphines via donor–acceptor inter­actions (Stallinger et al., 2007). The central carbon atom exhibits two lone electron pairs and can also be referred to as a phospho­rus double ylide.

Treatment of our PCP pincer ligand system [CH(dppm)₂]Cl (Stallinger et al., 2007) with [Ir^ICl(cod)]₂ causes a threefold coordination of the iridium(I) transition metal, a deprotonation of the carbodi­phospho­rane carbon atom, followed by a protonation and a subsequent oxidation of the iridium(I) center. Addition of ethyl diazo­acetate (EDA) to [Ir{C(dppm)₂-κ³P,C,P′}ClH(MeCN)]Cl complex 1 (Scheme 1) leads to a carbon–carbon coupling reaction via extrusion of a dppm subunit, which is stabilized by two phospho­rus–iridium(III) electron donor–acceptor inter­actions under the formation of a four-membered chelate ring. This reaction sequence, produced by the inter­action of the doubly ylidic carbon atom with an electrophile containing the extraordinarily good di­nitro­gen withdrawing group, may be described as Wittig-type carbon–carbon coupling reaction, which has rarely been reported in carbodi­phospho­rane chemistry (Kolodiazhnyi, 1999; Petz & Frenking, 2010). Furthermore, in analogy to Schmidbaur (1983), a specification of the process as a substitution reaction, during which one phosphine is replaced by a carbene ligand, is possible. The alkyl­idene C(dppm) unit coordinates the iridium(III) metal center in a κ²P,C manner. Overall, the carbodi­phospho­rane has been converted into a phospho­rus ylide ligand. Perpendicularly located to the dppm and C(dppm) units, the iridium(III) center coordinates a hydrido and a chlorido ligand trans to each other. Reaction of the monocationic [Ir{C(C₄H₆O₂)(dppm)-κ²P,C}Cl(dppm)H]Cl complex 2 with two equivalents of thallium(I)tri­fluoro­methane­sulfonate (TfOTl) causes the removal of the chlorido ligand and the chloride counter-ion with concomitant coordination of the acetate carbonyl oxygen atom in a facial manner, resulting in formation of the dicationic [Ir{C(C₄H₆O₂)(dppm)-κ³P,C,O}(dppm)H](CF₃O₃S)₂ complex 3.

A similar ligand arrangement in the coordination sphere of manganese(I) was previously mentioned by Ruiz et al. (2005). Protonation of the σ-alkynyl functionality of the [Mn^I(C≡C—CO₂Me)(CO)₃(dppm)] complex at low temperature generates the corresponding vinyl­idene [Mn^I(C=CH—CO₂Me)(CO)₃(dppm)]BF₄ complex, which rearranges via insertion of the vinyl­idene ligand into the manganese–phospho­rus bond upon warming to room temperature to an [Mn^I{(dppm)C=CH(CO₂Me)}(CO)₃]BF₄ complex. Exposure of complex 3 to carbon monoxide gas cleaves the iridium(III) carbonyl oxygen bond under coordination of a carbonyl ligand. Up to now, we have been unable to obtain suitable single crystals of complexes 1 and 2; however, it proved possible to crystallize the [Ir{C(C₄H₆O₂)(dppm)-κ³P,C,O}(dppm)H](CF₃O₃S)₂ (3) and [Ir{C(C₄H₆O₂)(dppm)-κ²P,C}(CO)(dppm)H](CF₃O₃S)₂ (4) products, the latter as a mixed di­chloro­methane–ethyl acetate solvate.

2. Structural commentary

The single crystal data for 3 reveal an ortho­rhom­bic crystal system in space group P2₁2₁2₁ (Fig. 1). The complex can be described as an asymmetric dicationic Ir^III complex, stabilized by two tri­fluoro­methane­sulfonate counter-ions. The iridium(III) centre is coordinated in a facial mode by the PCO pincer ligand system via a phosphine functionality, an ylidic carbon atom and a carbonyl oxygen atom of the ester group. The coordination sphere of the iridium(III) atom is completed by one bidentate dppm and one hydrido ligand. Furthermore, all phospho­rus atoms and the iridium atom are positioned in a common plane and the carbonyl oxygen atom as well as the hydride anion are located perpendicularly to this plane, trans to each other. The iridium center creates with its coordination sphere a distorted octa­hedral geometry and the deviations are caused by the presence of the strained four-membered dppm chelate ring [P3—Ir1—P4 = 70.2 (1)°] and the tridentate PCO ligand [C1—Ir1—O1 = 75.5 (2)°; C1—Ir1—P1 = 79.45 (17)°; O1—Ir1—P1 = 109.2 (1)°]. A C1—C4 distance of 1.335 (9) Å indicates a double bond and the sum of angles of 358.3° [C4—C1—P2 = 124.8 (5)°; C4—C1—Ir1 = 118.0 (5)°; P2—C1—Ir1 = 115.5 (3) °] permits the designation of the C1 surroundings as a planar surface. The Ir1—O1 bond length of 2.239 (4) Å is close to the value [2.262 (4) Å] in the related [Ir(CO₂CH₃){C(CO₂CH₃)CH(CO₂CH₃)}(PPh₃)(2-Ph₂PC₆H₄NH)] complex (Dahlenburg & Herbst, 1999).

Figure 1 Structure of complex 3 with displacement ellipsoids drawn at the 30% probability level. For clarity, only the ipso carbon atoms of the phenyl groups are shown and the counter-ions are omitted.

The solvated complex 4 crystallizes in the monoclinic space group P2₁/c and each asymmetric unit contains two closely related formula units. Complex 4 can be described as a bulky dicationic iridium(III) complex, which is stabilized by two tri­fluoro­methane­sulfonate counter-ions (Fig. 2). In comparison with complex 3, many structural characteristics are similar. The iridium(III) metal atom shows a distorted octa­hedral geometry. It coordinates a dppm unit and a PCO pincer ligand system in a meridional manner and, perpendicular to this plane, a hydrido ligand. The only difference is that the carbonyl oxygen atom of the PCO ligand system is uncoordinated and has been substituted by a carbonyl ligand. The carbonyl ligand reveals relatively long Ir1—C8 [1.965 (15) Å] and C8—O3 [1.116 (14) Å] distances, caused by the location trans to the hydrido ligand. Moreover, the substitution results in an overall lengthening of the Ir—P and the Ir—C separations (Table 1). This effect is especially pronounced for the Ir1—C1 value, which rises by an amount of 0.07 Å. Additionally, the substitution causes an approximation of the C1—Ir1—P1 angle [88.5 (3)°] to a regular octa­hedral angle of about 90° and an increase of the C4—C1—Ir1 angle to a value of 134.0 (9)°. Notably, the coordination of the carbonyl functionality has almost no effect on the C1—C4 double bond (Table 1) and considered in total the planar environment of the C1 atom [sum of the angles (C4—C1—P2; C4—C1—Ir1; P2—C1—Ir1) = 359.2°] is barely affected. The sequence of ligand replacements and reorganizations for 2, 3 and 4 are shown in Fig. 3.

Figure 2 Structure of one of the two independent units in complex 4 with displacement ellipsoids drawn at the 30% probability level. For clarity, only the ipso carbon atoms of the phenyl groups are shown and the counter-ions and solvent mol­ecules are omitted.

Figure 3 The sequence of ligand replacements and reorganizations accompanying the transformation of 2 into 3 and then 4.

3. Supra­molecular features

In the crystal of 3, the counter-ions inter­act with the hydrido ligand and with the hydrogen atoms of the dppm methyl­ene groups, leading to C⋯O and C⋯F separations of between 3.188 (11) and 3.473 (10) Å (Table 2). Such inter­actions are well known in connection with dppm and related ligand systems (Jones & Ahrens, 1998).

Table 2 Hydrogen-bond geometry (Å, °) for 3 D—H⋯A D—H H⋯A D⋯A D—H⋯A C2—H2A⋯O11 0.98 2.53 3.420 (9) 151 C3—H3A⋯F15Ai 0.98 2.48 3.310 (19) 142 C6—H6A⋯O14Ai 0.98 2.55 3.34 (3) 138 C6—H6B⋯O15A 0.98 2.38 3.32 (3) 160 C106—H106⋯O11 0.94 2.39 3.293 (10) 162 C108—H108⋯O1 0.94 2.43 3.255 (8) 147 C112—H112⋯O12ii 0.94 2.55 3.164 (9) 123 C206—H206⋯O11 0.94 2.61 3.473 (10) 152 C212—H212⋯O13iii 0.94 2.55 3.220 (9) 129 C306—H306⋯O1 0.94 2.61 3.396 (8) 141 C312—H312⋯O13iv 0.94 2.51 3.298 (9) 141 C406—H406⋯O16i 0.94 2.63 3.188 (11) 119 Symmetry codes: (i) ; (ii) ; (iii) ; (iv) .

In the extended structure of 4, the complex shows additional inter­actions between the tri­fluoro­methane­sulfonate counter-ions and the hydrido ligand and the hydrogen atoms of the dppm methyl­ene groups, respectively (Table 3).

Table 3 Hydrogen-bond geometry (Å, °) for 4 D—H⋯A D—H H⋯A D⋯A D—H⋯A C2—H2A⋯O43 0.98 2.23 3.190 (15) 165 C3—H3B⋯O41i 0.98 2.44 3.404 (14) 167 C12—H12B⋯O25i 0.98 2.26 3.226 (14) 170 C13—H13A⋯O38ii 0.98 2.58 3.538 (15) 167 C13—H13B⋯O26 0.98 2.48 3.446 (15) 169 C16—H16B⋯O20iii 0.98 2.48 3.15 (2) 125 C102—H102⋯O39 0.94 2.47 3.379 (17) 162 C108—H108⋯O11i 0.94 2.57 3.248 (15) 129 C202—H202⋯O39 0.94 2.57 3.508 (16) 178 C212—H212⋯O43 0.94 2.55 3.471 (15) 167 C306—H306⋯O11i 0.94 2.53 3.409 (16) 155 C312—H312⋯O41i 0.94 2.46 3.374 (16) 166 C402—H402⋯O11i 0.94 2.52 3.429 (15) 164 C506—H506⋯O12i 0.94 2.50 3.420 (17) 165 C508—H508⋯O38ii 0.94 2.56 3.284 (16) 134 C602—H602⋯O12i 0.94 2.59 3.519 (16) 172 C612—H612⋯O25i 0.94 2.59 3.511 (17) 165 C706—H706⋯O38ii 0.94 2.47 3.327 (16) 151 C712—H712⋯O26 0.94 2.41 3.335 (18) 167 C806—H806⋯O38ii 0.94 2.52 3.406 (16) 158 C808—H808⋯O4 0.94 2.48 2.964 (16) 112 C25—H25B⋯O24 0.98 2.53 3.14 (3) 121 C25A—H25D⋯O24 0.98 2.19 3.10 (9) 153 C16—H16B⋯O20iii 0.98 2.48 3.15 (2) 125 Symmetry codes: (i) x+1, y, z; (ii) x, y+1, z; (iii) .

4. Synthesis and crystallization

The [CH(dppm)₂]Cl compound was prepared by a previously reported procedure (Reitsamer et al., 2012); other starting materials and solvents were obtained from commercial suppliers. All preparations were carried out under an inert gas atmosphere of di­nitro­gen by the use of standard Schlenk techniques. The ¹H, ¹³C and ³¹P NMR spectra were recorded on a Bruker DPX 300 NMR spectrometer and were referenced against the solvent peaks of di­chloro­methane, chloro­form or aceto­nitrile, respectively, or, in the case of the ³¹P nucleus, against an external aqueous 85% H₃PO₄ standard. The phospho­rus atoms in the NMR data are labelled as in Figs. 1 and 2.

Synthesis of [Ir{C(dppm)₂-κ³P,C,P′}ClH(MeCN)]Cl (1): A mixture of 0.1 ml MeCN, 20.4 mg of [CH(dppm)₂]Cl (0.0250 mmol) and 8.4 mg of [IrCl(cod)]₂ (0.0125 mmol) was stirred for 1 min. The resulting solution contains predominantly the well known [Ir{CH(dppm)₂-κ³P,C,P′}(cod)]Cl₂ (Partl et al., 2018) and minor amounts of the [Ir{C(dppm)₂-κ³P,C,P′}ClH(MeCN)]Cl complex 1. ³¹P {¹H} NMR (CH₂Cl₂/C₂H₃N, 5:1): δ = 1.5 (vt, P1/P4, N = 70.4 Hz), 31.5 (vt, P2/P3) p.p.m.; ¹³C {¹H} NMR (CD₂Cl₂ / C₂D₃N, 5:1): δ = −28.9 (t, C1, ¹J_P2/P3C1 = 99.6 Hz) p.p.m.; ¹H NMR (CDCl₃/C₂D₃N, 5:1): δ = −21.3 (t, hydride, ²J_PH = 13.2 Hz) p.p.m.

Synthesis of [Ir{C(C₄H₆O₂)(dppm)-κ²P,C}Cl(dppm)H]Cl (2): While stirring the aforementioned MeCN solution of [Ir{CH(dppm)₂-κ³P,C,P′}(cod)]Cl₂ and [Ir{C(dppm)₂-κ³P,C,P′}ClH(MeCN)]Cl (1), 0.26 ml of CHCl₃ and 0.24 ml of a solution of ethyl diazo­acetate in CHCl₃ (c = 0.105 mol l⁻¹; 0.025 mmol) were added successively. The [Ir{CH(dppm)₂-κ³P,C,P′}(cod)]Cl₂ by-product is slowly transformed to 1, which in turn reacts with ethyl diazo­acetate. After standing for 24 h, product 2 was generated almost qu­anti­tatively. ³¹P {¹H} NMR (CHCl₃/C₂H₃N, 5:1): δ = 26.5 (ddd, P1, ²J_P1P2 = 52.1 Hz, ²J_P1P3 = 16.8 Hz, ²J_P1P4 = 371.1 Hz), 45.7 (ddd, P2, ³J_P2P3 = 18.4 Hz, ⁴J_P2P4 = 7.3 Hz), −52.5 (ddd, P3, ²J_P4P3 = 30.6 Hz), −36.7 (ddd, P4) p.p.m.; ¹³C {¹H} NMR (CDCl₃/C₂D₃N, 5:1): δ = 139.2 (dddd, C1, ²J_P1C1 = 6.9 Hz, ¹J_P2C1 = 6.9 Hz, ²J_P3C1 = 6.9 Hz, ²J_P4C1 = 98.2 Hz) p.p.m.; ¹H NMR (CDCl₃/C₂D₃N, 5:1): δ = −17.7 (ddd, hydride, ²J_P1H = 9.9 Hz, ²J_P3H = 9.9 Hz, ²J_P4H = 9.9 Hz) p.p.m.

Synthesis of [Ir{C(C₄H₆O₂)(dppm)-κ³P,C,O}(dppm)H](CF₃O₃S)₂ (3): 21.2 mg of thallium(I) tri­fluoro­methane­sulfonate (0.0597 mmol) were dissolved in MeOH (0.1 ml) and added to a solution of complex 2 (0.025 mmol) in chloro­form/aceto­nitrile (5:1). After stirring for 15 min the precipitated TlCl was separated, all solvents were removed and complex 3 was obtained (34.0 mg, 100%). Single beige–white crystals of complex 3 were grown slowly from acetone (0.5 ml), covered with 0.3 ml of hexane. ³¹P {¹H} NMR (CHCl₃/C₂H₃N, 5:1): δ = 9.1 (ddd, P1, ²J_P1P2 = 27.6 Hz, ²J_P1P3 = 13.0 Hz, ²J_P1P4 = 311.2 Hz), 36.0 (ddd, P2, ³J_P2P3 = 13.8 Hz), −44.2 (ddd, P3, ²J_P3P4 = 35.2 Hz), −33.1 (dd, P4) p.p.m.; ¹³C {¹H} NMR (CDCl₃): δ = 181.4 (dddd, C1, ³J_P1C1 = 6.1 Hz, ¹J_P2C1 = 34.8 Hz, ²J_P3C1 = 81.2 Hz, ²J_P4C1 = 2.8 Hz) p.p.m.; ¹H NMR (CDCl₃): δ = −23.3 (ddd, hydride, ²J_PH = 6.7 Hz, ²J_PH = 12.1 Hz, ²J_PH = 20.8 Hz) p.p.m.

Synthesis of [Ir{C(C₄H₆O₂)(dppm)-κ²P,C}(CO)(dppm)H](CF₃O₃S)₂ (4): Complex 3 was dissolved in CHCl₃ (0.6 ml), the mixture was filtered and the solution was placed in an atmos­phere of CO. After standing for 16 h product 4 was formed and single crystals were obtained via layering of a solution of complex 4 dissolved in CH₂Cl₂ with EtOAc. ³¹P {¹H} NMR (CHCl₃/CH₃OH): δ = 5.3 (ddd, P1, ²J_P1P2 = 50.3 Hz, ²J_P1P3 = 16.9 Hz, ²J_P1P4 = 296.0 Hz), 57.1 (ddd, P2, ³J_P2P3 = 15.3 Hz, ³J_P2P4 = 12.3 Hz), −55.6 (ddd, P3, ²J_P3P4 = 32.8 Hz), −44. 7 (ddd, P4) p.p.m.; ¹³C {¹H} NMR (CDCl₃/CD₃OD): δ = 134.8 (ddd, C1, ¹J_C1P2 = 6.9 Hz, ²J_C1P3 = 98.2 Hz) p.p.m.; ¹H NMR (CDCl₃/CD₃OD): δ = −8.8 (t, hydride, ²J_PH = 13.5 Hz) p.p.m.

5. Refinement

Crystal data, data collection and structure refinement details are summarized in Table 4. The data for both 3 and 4 were processed without absorption corrections. In relation to the structure determination of complex 3, the hydrido ligand was detected and refined isotropically. One tri­fluoro­methane­sulfonate counter-ion shows positional disorder in a 2:1 ratio, caused by an overlying of the C9, O16 and F16 positions. These positions were also refined isotropically. The structure determination of complex 4 resulted in the detection of pseudo-merohedral twinning (matrix: 0 0 0 0 1 0 1). Furthermore, the hydrido ligand was determined and refined isotropically by the use of a bond restraint of 1.6 Å and a fixed U_iso value. The solvent di­chloro­methane shows disorder over two orientations, which can be described with occupation factors 0.5 and 0.166. Refinement of this solvent mol­ecule was carried out by the usage of bond restraints and isotropic displacement parameters. Furthermore, the ethyl acetate mol­ecule was located and modelled with equal anisotropic displacement parameters for O21, C22 and C23. H atoms bound to Ir1 and C4 were located in a difference-Fourier map and refined isotropically. Other H atoms were positioned geometrically and refined using a riding model with C—H = 0.94–0.98 Å and U_iso(H) = 1.2U_eq(C).

Table 4 Experimental details   3 4 Crystal data Chemical formula [IrH(C30H28O2P2)(C25H22P2)](CF3O3S)2 [IrH(C30H28O2P2)(C25H22P2)(CO)](CF3O3S)2·0.33CH2Cl2·0.5C4H8O2 Mr 1358.17 1458.54 Crystal system, space group Orthorhombic, P212121 Monoclinic, P21/c Temperature (K) 233 233 a, b, c (Å) 11.3249 (1), 21.3629 (3), 23.4125 (3) 14.4712 (3), 20.9611 (5), 41.3651 (9) α, β, γ (°) 90, 90, 90 90, 100.108 (1), 90 V (Å3) 5664.25 (12) 12352.6 (5) Z 4 8 Radiation type Mo Kα Mo Kα μ (mm−1) 2.62 2.44 Crystal size (mm) 0.41 × 0.05 × 0.04 0.15 × 0.09 × 0.04   Data collection Diffractometer Nonius KappaCCD Nonius KapppCCD No. of measured, independent and observed [I > 2σ(I)] reflections 36212, 9983, 9331 45373, 18805, 14603 Rint 0.046 0.068 θmax (°) 25.0 24.0 (sin θ/λ)max (Å−1) 0.595 0.572   Refinement R[F2 > 2σ(F2)], wR(F2), S 0.029, 0.062, 1.03 0.054, 0.108, 1.04 No. of reflections 9983 18805 No. of parameters 701 1530 No. of restraints 0 5 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 Δρmax, Δρmin (e Å−3) 0.62, −0.62 1.90, −0.93 Absolute structure Flack x determined using 3851 quotients [(I+)−(I−)]/[(I+)+(I−)] (Parsons et al., 2013) – Absolute structure parameter −0.006 (2) – Computer programs: COLLECT (Nonius, 1999), DENZO and SCALEPACK (Otwinowski & Minor, 1997), XP in SHELXTL and SHELXS97 (Sheldrick, 2008), SHELXL2014/7 (Sheldrick, 2015) and ChemDraw (Cambridge Soft, 2001).