Synthesis and characterization of cationic dicarbonyl Fe(II) PNP pincer complexes.

ABSTRACT: In the present work, we have prepared a series of octahedral Fe(II) complexes of the type trans-[Fe(PNP)(CO)2Cl]+-PNP are tridentate pincer-type ligands based on 2,6-diaminopyridine. These complexes are formed irrespective of the size of the substituents at the phosphorus sites and whether cis-[Fe(PNP)(Cl2)(CO)] or trans-[Fe(PNP)(Cl2)(CO)] are reacted with CO in the presence of 1 equiv of silver salts. X-ray structures of representative complexes are presented. Based on simple bonding considerations the selective formation of trans-dicarbonyl Fe(II) complexes is unexpected. In fact, DFT calculations confirm that trans-dicarbonyl complexes are indeed thermodynamically disfavored over the respective cis-dicarbonyl compounds, but are favored for kinetic reasons.

Introduction

As part of our ongoing research on the synthesis and reactivity of iron(II) PNP pincer complexes [1-3], we recently prepared the cationic dicarbonyl complex trans-[Fe(PNP-iPr)(CO)2Cl]+ (PNP-iPr = N,N′-bis(diisopropyl)-2,6-diaminopyridine) (trans-2a) as shown in Scheme 1 [4]. The formation of this complex was somewhat unexpected as it features two CO ligands in a mutual trans position. In fact, simple bonding considerations suggest that the unobserved cis isomers are the more stable one. This was indeed also supported by DFT calculations. This complex is interesting, since the trans CO arrangement makes one of the CO ligands comparatively labile which can be replaced by other potential ligands. Accordingly, trans-[Fe(PNP-iPr)(CO)2Cl]X with X = BF4− turned out to be an efficient precatalyst for the coupling of aromatic aldehydes with ethyl diazoacetate to selectively give 3-hydroxyacrylates rather than β-keto esters [5].

In continuation of our studies on iron PNP complexes, we herein report on the synthesis and reactivity of a series octahedral Fe(II) carbonyl complexes bearing both sterically little demanding as well as bulky PNP ligands in order to probe whether sterics influences the preference for a trans- over a cis-dicarbonyl arrangement. Moreover, we investigate the impact of the NR linker on the outcome of these reactions.

Results and discussion

Treatment of complexes cis-1b and trans-1c–1g (1f and 1g are mixtures of cis and trans isomers) with 1 equiv of Ag+ salts (with SbF6−, BF4−, or CF3SO3− as counterions) in THF or acetone in the presence of CO at room temperature selectively afforded the cationic complexes trans-[Fe(κ3P,N,P-PNP)(CO)2X]+ (trans-2b–2g) in 78–98 % isolated yields (Scheme 1). The respective cis-dicarbonyl complexes were not observed and, hence, sterics and also the amine linker (NR) apparently do not influence the preference for a trans-dicarbonyl geometry. This is also supported by DFT calculations (vide infra). These complexes are thermally robust red solids that are air stable both in the solid state and in solution for several days. Characterization was accomplished by elemental analysis and 1H, 13C{1H}, 31P{1H} NMR and IR spectroscopy. In addition, the solid state structures of trans-2b, trans-2d, trans-2f, and trans-2g were determined by single-crystal X-ray diffraction.

In the IR spectrum, as expected, the CO ligands exhibit only one band between 1979 and 2031 cm−1 for the mutually trans CO ligands which are assigned to the asymmetric CO stretching frequency. The symmetric CO stretching band is IR inactive and not observed. The 31P{1H} NMR spectrum of complexes trans-2b–2g show singlet resonances at 85.0, 92.3, 100.7, 96.7, 130.6, and 132.8 ppm, respectively. In the 13C{1H} NMR spectrum the two CO ligands exhibit a single low-intensity triplet resonance in the range of 207.2–211.8 ppm, thus clearly revealing that the two CO ligands are trans to one another.

Structural views of trans-2b, trans-2d, trans-2f, and trans-2g are depicted in Figs. 1, 2, 3 and 4 with selected bond distances and angles reported in the captions. All complexes adopt a distorted octahedral geometry around the metal center with the CO ligands in trans position to one another. The PNP ligand is coordinated to the iron center in a typical tridentate meridional mode, with P–Fe–P angles between 167.8° and 169.1°. The C(CO)–Fe–C(CO) angles vary between 168.7° and 174.4°. The compounds with NH linkers show, as a typical feature, hydrogen bonds between the NH-groups of the cationic Fe(PNP) complexes and the counterions BF4− and CF3SO3−.

Fig. 1

Structural view of trans-[Fe(PNP-Ph)(CO)2Cl]SbF6 (trans-2a) showing 50 % thermal ellipsoids (H atoms and counterion omitted for clarity). Selected bond lengths (Å) and bond angles (°): Fe1–Cl1 2.3029(7), Fe1–P2 2.2190(7), Fe1–P1 2.2317(7), Fe1–C30 1.824(3), Fe1–C31 1.850(3), Fe1–N1 1.977(2), P2–Fe1–P1 168.33(3), C30–Fe1–C31 172.6(1)

Fig. 2

Structural view of trans-[Fe(PNP-Et)(CO)2Cl]CF3SO3 (trans-2c) showing 50 % thermal ellipsoids (H atoms and counterion omitted for clarity). Selected bond lengths (Å) and bond angles (°): Fe1–Cl1 2.3116(4), Fe1–P1 2.2265(4), Fe1–P2 2.2302(4), Fe1–N1 1.983(1), Fe1–C14 1.823(1), Fe1–C15 1.837(1), P1–Fe1–P2 167.82(2), C14–Fe1–C15 172.15(6)

Fig. 3

Structural view of trans-[Fe(PNPMe-iPr)(CO)2Cl]BF4 (trans-2e) showing 50 % thermal ellipsoids (H atoms and counterion omitted for clarity). Selected bond lengths (Å) and bond angles (°): Fe1–Cl1 2.3009(5), Fe1–P1 2.2507(5), Fe1–P2 2.2455(5), Fe1–N1 1.976(1), Fe1–C20 1.818(1), Fe1–C21 1.819(1), P1–Fe1–P2 168.33(2), C20–Fe1–C21 168.71(7)

Fig. 4

Structural view of trans-[Fe(PNPEt-iPr)(CO)2Cl]BF4 (trans-2f) showing 50 % thermal ellipsoids (H atoms and counterion omitted for clarity). Selected bond lengths (Å) and bond angles (°): Fe1–Cl1 2.3034(3), Fe1–P1 2.2494(3), Fe1–P2 2.2598(3), Fe1–N1 1.9713(7), Fe1–C22 1.8126(10), Fe1–C23 1.8316(8), P1–Fe1–P2 169.14(1), C22–Fe1–C23 174.40(5)

To better understand why trans-dicarbonyl complexes are preferred over cis-dicarbonyl complexes, DFT calculations were performed with the N2,N6-bis(dimethylphosphanyl)-pyridine-2,6-diamine ligand (PNP-Me) as model. The starting point of our calculations are the coordinatively unsaturated cationic intermediates [Fe(PNP-Me)(CO)Cl]+ (A and/or B), which are formed from trans-[Fe(κ3P,N,P-PNP-Me)(CO)Cl2] (trans-1c) upon irreversible removal of chloride with silver salts (Scheme 2). The analogous cis isomer is experimentally not accessible. The energy profile (DFT/OPBE) for the cis/trans isomerization of [Fe(PNP-Me)(CO)Cl]+ is shown in Fig. 5.

Fig. 5

Energy profile (DFT/OPBE) for the cis/trans isomerization of pentacoordinated intermediates [Fe(PNP-Me)(CO)Cl]+ with the LUMO’s and the SOMO of 1 A, B, and A, respectively. The energy values (kJ mol−1) are referred to the cationic singlet intermediate [Fe(PNP-Me)(CO)Cl]+ ( B). The plain curve corresponds to the spin singlet surface (S = 0) and the dashed curve corresponds to the spin triplet surface (S = 1)

According to the calculations both cationic pentacoordinated intermediates A and B adopt a square pyramidal geometry where the Cl and the CO ligands, respectively, are in the apical position. The singlet ground state B is the energetically favored species by 22.6 and 50.7 kJ mol−1, respectively, over the singlet and triplet states of A (A, A) (Fig. 5). In the case of B, no stable triplet state was found. A and B were found to interconvert readily via two pathways. A is able to isomerize along the spin singlet surface (S = 0) to give B with a small energy barrier of 11.3 kJ mol−1. This reaction proceeds via transition state TS. In the second pathway, A undergoes two consecutive spin state changes (spin crossover) from S = 0 to S = 1 and back to S = 0. The minimum energy crossing point1 between the potential energy surfaces of the two spin states S = 0 to S = 1 (CP2) is easily accessible lying merely 1.3 kJ mol−1 above A. The second spin state change from S = 1 to S = 0 proceeds via CP1 with a barrier of 19.3 kJ mol−1.

Finally, the experimentally isolated trans-2c (which is actually is less stable than cis-2c by 17.2 kJ mol−1) is formed by an essentially barrierless addition of CO to B which is the most stable and predominant species lying 50.7 kJ mol−1 lower in energy than A. In general, CO addition at singlet intermediates is generally more favorable than at triplet intermediates as can be seen by examining the frontier orbitals of the relevant species. The LUMO of the pentacoordinated intermediates with a singlet spin state (A and B) are formed mainly by z2-type orbitals centered at the Fe-atom and pointing towards the empty coordination position (Fig. 5). Therefore, these orbitals are ready to receive a pair of electrons from a ligand that occupies the sixth coordination site (CO in this case) and establish the corresponding σ-bond. In the case of spin triplet intermediate (A), this orbital is occupied being, in fact, the highest single occupied molecular orbital (SOMO) of this species (Fig. 5). This is easily available to receive the electron pair from an incoming CO rendering addition of this ligand a difficult process. In fact, the first empty orbital (LUMO) in the case of the triplet intermediate corresponds to an x2–y2-type orbital which is centered on the metal and is antibonding (σ*) with respect to the four ligands in the equatorial plane.

Conclusion

In the present work we have prepared, spectroscopically and structurally characterized several octahedral iron(II) complexes of the type trans-[Fe(PNP)(CO)2X]+. These complexes are formed irrespective of the size of the substituents at the phosphorus sites and whether cis-[Fe(PNP)(Cl2)(CO)] or trans-[Fe(PNP)(Cl2)(CO)] are reacted with CO in the presence of 1 equiv of silver salts. Based on simple bonding considerations the selective formation of trans-dicarbonyl Fe(II) complexes is unexpected. DFT calculations indeed confirm that trans-dicarbonyl complexes are thermodynamically disfavored over the respective cis-dicarbonyl compounds. The key to an understanding of this unexpected selectivity is the fact that upon irreversible removal of a chloride ligand from [Fe(PNP)(CO)Cl2] pentacoordinate intermediates [Fe(PNP)(CO)Cl]+ of two conformations, one with the chloride in the apical and CO in the basal position (A) and vice versa (B), are formed. The subsequent carbonylation process depends strongly on the complex geometry of the 16e intermediates [Fe(PNP)(CO)Cl]+, i.e., A vs. B, which in turn determines the spin state (S = 0 or S = 1) and consequently the reactivity and also the stability of these intermediates. According to calculations, B in the singlet ground state is the most stable and also kinetically the most accessible intermediate in solution. The formation of trans-[Fe(PNP)(CO)2Cl]+ is kinetically controlled with B being the key intermediate. The mechanism deduced from DFT calculations is in full agreement with experimental findings.

Experimental

All manipulations were performed under an inert atmosphere of argon by using Schlenk techniques or in an MBraun inert-gas glovebox. The solvents were purified according to standard procedures [7]. The deuterated solvents were purchased from Aldrich and dried over 4 Å molecular sieves. Complexes cis-[Fe(κ3P,N,P-PNP-Ph)(CO)Cl2] (cis-1b), trans-[Fe(κ3P,N,P-PNP-Me)(CO)Cl2] (trans-1c), trans-[Fe(κ3P,N,P-PNP-Et)(CO)Cl2] (trans-1d), trans-[Fe(κ3P,N,P-PNP-nPr)(CO)Cl2] (trans-1e), cis/trans-[Fe(PNPMe-iPr)(CO)Cl2] (cis/trans-1f), and cis/trans-[Fe(PNPEt-iPr)(CO)Cl2] (cis/trans-1 g) were prepared according to the literature [8]. 1H, 13C{1H}, and 31P{1H} NMR spectra were recorded on Bruker AVANCE-250 and AVANCE-400 spectrometers. 1H and 13C{1H} NMR spectra were referenced internally to residual protio-solvent and solvent resonances, respectively, and are reported relative to tetramethylsilane (δ = 0 ppm). 31P{1H} NMR spectra were referenced externally to H3PO4 (85 %) (δ = 0 ppm).

Trans-[(chloro)[N2,N6-bis(diphenylphosphanyl)pyridine-2,6-diamine](dicarbonyl)iron(II)] tetrafluoroborate (trans-[Fe(κ3P,N,P-PNP-Ph)(CO)2Cl]BF4) (trans-2b, C31H25BClF4FeN3O2P2)

Complex cis-1b (200 mg, 0.316 mmol) was dissolved in 10 cm3 THF, CO gas was bubbled through the solution and 62 mg AgBF4 (0.316 mmol) was added. After 4 h the red solution was filtered over Celite and the solvent was evaporated. The red powder was washed with 20 cm3 Et2O and dried under vacuum. Yield 180 mg (85 %); 1H NMR (acetone-d, 20 °C): δ = 9.50 (s, 2H, NH), 8.10 (m, 5H, Ph, py4), 7.71 (m, 18H, Ph, py3,5) ppm; 13C{1H} NMR (CD2Cl2): δ = 207.2 (t, J = 25.8 Hz, CO), 161.3 (py), 141.8 (py), 134.6–133.2 (Ph), 132.10 (Ph), 131.0–129.8 (Ph), 129.2 (t, J = 5.4 Hz, Ph), 102.2 (py) ppm; 31P{1H} NMR (acetone-d, 20 °C): δ = 85.0 ppm; IR (ATR, 20 °C):  = 2031 (νC=O) cm−1.

Trans-[(chloro)[N2,N6-bis(dimethylphosphanyl)pyridine-2,6-diamine](dicarbonyl)iron(II)] trifluoromethanesulfonate (trans-[Fe(κ3P,N,P-PNP-Me)(CO)2Cl]CF3SO3) (trans-2c, C12H17ClF3FeN3O5P2S)

CO was bubbled through a suspension of 100 mg trans-1b (0.26 mmol) and 67 mg AgCF3SO3 (0.26 mmol) in 7 cm3 acetone. The orange solution was then filtrated over Celite, evaporated to dryness and the obtained solid was washed with 10 cm3n-hexane. The orange powder was dried under reduced pressure. Yield 134 mg (98 %); 1H NMR (acetone-d, 20 °C): δ = 8.46 (s, 2H, NH), 7.33 (t, J = 7.9 Hz, 1H, py4), 6.23 (d, J = 8.0 Hz, 2H, py3,5), 2.38 (m, 12H, CH3) ppm; 13C{1H} NMR (acetone-d, 20 °C): δ = 210.3 (t, J = 26.8 Hz, CO), 162.4 (t, J = 7.5 Hz, py), 141.9 (py), 101.1 (t, J = 3.8 Hz, py), 18.9 (t, J = 17.2 Hz, CH3) ppm; 31P{1H} NMR (acetone-d, 20 °C): δ = 92.3 ppm; IR (ATR):  = 1979 (νCO) cm−1.

Trans-[(chloro)[N2,N6-bis(diethylphosphanyl)pyridine-2,6-diamine](dicarbonyl)iron(II)] trifluoromethanesulfonate (trans-[Fe(κ3P,N,P-PNP-Et)(CO)2Cl]CF3SO3) (trans-2c, C16H25ClF3FeN3O5P2S)

This compound was prepared analogously to trans-2b with 120 mg trans-1c (0.27 mmol) and 70 mg AgCF3SO3 (0.27 mmol) as starting materials. The orange product was dried under reduced pressure. Yield: 153 mg (97 %). Crystals were grown from an acetone solution of 2c by slow diffusion of Et2O. 1H NMR (acetone-d, 20 °C): δ = 8.49 (2H, NH), 7.63 (1H, py4), 6.31 (d, J = 5.2 Hz, 2H, py3,5), 2.90 (4H, CH2), 2.78 (4H, CH2), 1.51 (12H, CH3) ppm; 13C{1H} NMR (acetone-d, 20 °C): δ = 210.5 (t, J = 25.2 Hz, CO), 161.8 (t, J = 6.9 Hz, py), 141.1 (py), 100.3 (py), 23.4 (t, J = 15.3 Hz, CH2), 6.4 (CH3) ppm; 31P{1H} NMR (acetone-d, 20 °C): δ = 100.7 ppm; IR (ATR):  = 2008 (νCO) cm−1.

Trans-[(chloro)[N2,N6-bis(dipropylphosphanyl)pyridine-2,6-diamine](dicarbonyl)iron(II)] trifluoromethanesulfonate (trans-[Fe(κ3P,N,P-PNP-nPr)(CO)2Cl]CF3SO3) (trans-2d, C20H33ClF3FeN3O5P2S)

This compound was prepared analogously to trans-2b using 150 mg trans-1d (0.30 mmol) and 78 mg AgCF3SO3 (0.30 mmol) as starting materials. The red–orange product was dried under reduced pressure. Yield: 177 mg (92 %); 1H NMR (acetone-d, 20 °C): δ = 8.41 (2H, NH), 7.47 (t, J = 7.9 Hz, 1H, py4), 6.41 (d, J = 7.6 Hz, 2H, py2,6), 2.01 (m, 8H, CH2), 1.58 (m, 8H, CH2), 1.12 (t, J = 7.1 Hz, 12H, CH3) ppm; 13C{1H} NMR (acetone-d, 20 °C): δ = 210.4 (t, J = 25.6 Hz, CO), 161.7 (t, J = 6.8 Hz, py), 140.9 (py), 100.2 (t, J = 3.7 Hz, py), 32.8 (t, J = 14.3 Hz, CH2), 16.2 (CH3), 15.0 (t, J = 7.8 Hz, CH2) ppm; 31P{1H} NMR (acetone-d, 20 °C): δ = 96.7 ppm; IR (ATR):  = 2011 (νCO) cm−1.

Trans-[(chloro)[N2,N6-bis(diisopropylphosphanyl)-N2,N6-dimethylpyridine-2,6-diamine](dicarbonyl)iron(II)] tetrafluoroborate (trans-[Fe(κ3P,N,P-PNPMe-iPr)(CO)2Cl]BF4) (trans-2e, C21H37BClF4FeN3O2P2)

CO was bubbled through a solution of 150 mg cis/trans-1e (0.30 mmol) and 59 mg AgBF4 (0.30 mmol) in 15 cm3 of THF. The pink solution was stirred under CO atmosphere for 1 h; then the solvent was removed under reduced pressure. The residue was redissolved in 15 cm3 of CH2Cl2, filtered and the volume of the solvent was reduced to about 0.5 cm3. The product was precipitated by addition of 40 cm3 of pentane, collected on a glass frit, washed with 15 cm3 of n-pentane, and dried under vacuum. Yield: 141 mg (78 %); 1H NMR (CD2Cl2, 20 °C): δ = 7.53 (t, J = 8.1 Hz, 1H, py4), 6.14 (d, J = 8.2 Hz, 2H, py3,5), 3.19 (m, 4H, CH(CH3)2), 3.08 (s, 6H, NCH3), 1.53–1.42 (m, 24H, CH(CH)2) ppm; 13C{1H} NMR (CD2Cl2, 20 °C): δ = 211.6 (t, J = 24.7 Hz, CO), 163.0 (vt, J = 7.4 Hz, py2,6), 142.2 (s, py4), 100.2 (vt, J = 2.7 Hz, py3,5), 35.4 (s, NCH3), 32.0 (vt, J = 11.2 Hz, CH(CH3)2), 18.5 (s, CH(CH3)2), 17.7 (s, CH(CH3)2) ppm; 31P{1H} NMR (CD2Cl2, 20 °C): δ = 130.6 ppm; IR (ATR):  = 2002 (νC=O) cm−1.

Trans-[(chloro)[N2,N6-bis(diisopropylphosphanyl)-N2,N6-diethylpyridine-2,6-diamine](dicarbonyl)iron(II)] tetrafluoroborate (trans-[Fe(κ3P,N,P-PNPEt-iPr)(CO)2Cl]BF4) (trans-2f, C23H41BClF4FeN3O2P2)

This complex was prepared analogously to trans-2e with 150 mg cis/trans-1f (0.29 mmol) and 56 mg AgBF4 (0.29 mmol) as starting materials. Yield: 131 mg (75 %); 1H NMR (CD2Cl2, 20 °C): δ = 7.54 (t, J = 8.2 Hz, 1H, py4), 6.17 (d, J = 8.2 Hz, 2H, py3,5), 3.58 (m, 4H, NCHCH3), 3.18 (m, CH(CH3)2), 1.49–1.10 (m, 30H, NCH2CH, CH(CH)2) ppm; 13C{1H} NMR (CD2Cl2, 20 °C): δ = 211.8 (t, J = 24.8 Hz, CO), 162.3 (vt, J = 6.9 Hz, py2,6), 142.4 (s, py4), 101.2 (vt, J = 2.6 Hz, py3,5), 43.3 (s, NCH2CH3), 31.4 (vt, J = 10.8 Hz, CH(CH3)2), 19.1 (s, CH(CH3)2), 17.8 (s, CH(CH3)2), 13.0 (s, NCH2CH3) ppm; 31P{1H} NMR (CD2Cl2, 20 °C): δ = 132.8 ppm; IR (ATR):  = 2005 (νC=O) cm−1.

X-ray structure determination

X-ray diffraction data of trans-2a, trans-2c, trans-2e, and trans-2f (CCDC entries 1015363 (trans-2a), 1469956 (trans-2c), 1469957 (trans-2e), 1469958 (trans-2f),) were collected at T = 100 K in a dry stream of nitrogen on Bruker Kappa APEX II diffractometer systems using graphite-monochromatized Mo-Kα radiation (λ = 0.71073 Å) and fine sliced φ- and ω-scans. Data were reduced to intensity values with SAINT and an absorption correction was applied with the multi-scan approach implemented in SADABS [9]. The structures of trans-2c, trans-2e, and trans-2f were solved by charge flipping using SUPERFLIP [10] and refined against with JANA2006 [11]. The structure of trans-2a was solved with direct methods and refined against F2 with the SHELX software package [12]. Non-hydrogen atoms were refined anisotropically. The H atoms connected to C atoms were placed in calculated positions and thereafter refined as riding on the parent atoms. The H atoms of the amine functionalities were located in difference Fourier maps and freely refined. Molecular graphics were generated with the program MERCURY [13].

Computational details

Calculations were performed using the Gaussian 09 software package, and the OPBE functional without symmetry constraints as already described previously [14].