Abstract
This work presents a comparative study of a series of halocarbonyl Mo(ii) and W(ii) complexes of the types [M(PNP)(CO)3X]X and [M(PNP)(CO)2X2] (M = Mo, W; X = I, Br), featuring PNP pincer ligands based on a 2,6-diaminopyridine scaffold. The complexes were prepared and fully characterized. The syntheses of these complexes were accomplished by treatment of [M(PNP)(CO)3] with stoichiometric amounts of I2 and Br2, respectively. The modification of the 2,6-diaminopyridine scaffold by introducing NMe and NPh instead of NH spacers with concomitant modification of the phosphine moieties changed the steric and electronic properties of the PNP ligand significantly. While in the case of NH linkers exclusively cationic seven-coordinate complexes of the type [M(PNP)(CO)3X](+) were obtained with NMe and NPh spacers neutral seven-coordinate complexes of the type [M(PNP)(CO)2X2] were afforded. In the case of the latter, when the reaction is performed in the presence of CO also [M(PNP)(CO)3X](+) complexes are formed which slowly lose CO to give [M(PNP)(CO)2X2]. The halocarbonyl tungsten chemistry parallels that of molybdenum. The only exception is molybdenum in conjunction with the PNP(Me)-iPr ligand, where the coordinatively unsaturated complex [Mo(PNP(Me)-iPr)(CO)X2] is formed. DFT mechanistic studies reveal that the seven-coordinate complexes should be the thermodynamic as well as the kinetic products. Since [Mo(PNP(Me)-iPr)(CO)X2] is the observed product it suggests that the reaction follows an alternative path. Structures of representative complexes were determined by X-ray single crystal analyses.
Highlights
Seven coordinate halocarbonyl Mo(II) and W(II) complexes of the type [ML3(CO)3X] where M is Mo, W; X = Cl, Br, I and L3 are neutral (z = 0) or anionic (z = −1) tridentate ligands adopting fac geometries such as Cp, Cp*, trispyrazolylborates, trispyrazolylmethanes, 1,4,7-triazacyclononane, or 1,5,9triphosphacyclododecane are a common class of compounds
Templeton and coworkers described the synthesis of a series of halocarbonyl tungsten pincer complexes featuring the silazane-based PNP pincer-type ligand HN (SiMe2CH2PPh2)2.2 We have recently described the synthesis of a series of Mo(II) PNP halocarbonyl complexes of the type [Mo (PNP)(CO)3X]+ (X = I, Br, Cl) (I), and complexes of the less common type [Mo(PNP)(CO)2X2] (X = I, Br, Cl, F) (II) and, in one case, of the unusual type [Mo(PNP)(CO)X2] (X = I, Br, Cl) (III) as illustrated in Scheme 2.3–6 The latter is a coordinatively unsaturated 16e low spin complex and, based on DFT calculations, is surprisingly thermodynamically unfavorable as compared to types I and II
In continuation of our studies on group six PNP pincer complexes, we report here on the synthesis, characterization, and reactivity of various new halocarbonyl W(II) as well as halocarbonyl Mo(II) PNP pincer complexes featuring different substituents at the phosphine moieties and on the amine linkers (Chart 1)
Summary
Scheme 1 Oxidative addition of X2 to fac-[ML3(CO)3]z. have been rarely studied. Templeton and coworkers described the synthesis of a series of halocarbonyl tungsten pincer complexes featuring the silazane-based PNP pincer-type ligand HN (SiMe2CH2PPh2)2.2 We have recently described the synthesis of a series of Mo(II) PNP halocarbonyl complexes of the type [Mo (PNP)(CO)3X]+ (X = I, Br, Cl) (I), and complexes of the less common type [Mo(PNP)(CO)2X2] (X = I, Br, Cl, F) (II) and, in one case, of the unusual type [Mo(PNP)(CO)X2] (X = I, Br, Cl) (III) as illustrated in Scheme 2.3–6 The latter is a coordinatively unsaturated 16e low spin complex and, based on DFT calculations, is surprisingly thermodynamically unfavorable as compared to types I and II (vide infra). The 13C{1H} NMR spectra of 3 and 4 show two low-field triplet carbonyl resonances in a 2 : 1 ratio in the
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