Glen P. Rosini scite author profile

The dihydride CpRe(PPh3)2H2 (1) catalyzes H/D exchange between C6D6 and other arenes or alkanes. Compound 1 also undergoes photochemical phosphine substitution with PMe3 to give CpRe(PPh3)(PMe3)H2 and then CpRe(PMe3)2H2. Mechanistic studies of these reactions are inconsistent with [CpRe(PPh3)H2] as an intermediate. An alternative mechanism is presented proposing that the active species for H/D exchange is the 14-electron cyclic allyl intermediate [(η3-C5H7)Re(PPh3)2] (E), in which both hydrides have migrated from the rhenium to the cyclopentadienyl ligand. This intermediate accounts for the fact that (1) deuterium does not exchange into the hydride ligands of complex 1 during the H/D exchange catalysis and (2) phosphine substitution occurs by an associative pathway. The precursor to intermediate E, [(η4-C5H6)Re(PPh3)2H] (D), can undergo reversible orthometalation, allowing H/D exchange between the hydride ligands and the ortho phosphine positions. Evidence is presented to support this new mechanism as well as to rule out other feasible mechanisms.

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Thermodynamics of Addition of H₂, CO, N₂, and C−H Bonds to M(PⁱPr₃)₂Cl (M = Ir, Rh). An Unprecedented Metal−Carbonyl Bond Strength

Rosini

Liu

Krogh‐Jespersen

et al. 1998

J. Am. Chem. Soc.

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The thermodynamics of interconversion of various complexes containing the unit IrL*2Cl (L* = P( i Pr)3) have been investigated by calorimetry and equilibrium measurements. These complexes span a wide range of configurations including four- and five-coordinate d8 (IrL*2ClL‘, IrL*2Cl(CO)2) and five- and six-coordinate d6 (IrL*2ClRH and IrL*2ClRH(CO)). On the basis of kinetic experiments, a lower limit to the Ir−N2 bond dissociation enthalpy (BDE) of IrL*2Cl(N2) has been determined (36 kcal/mol). Using this value as an “anchor”, in conjunction with the relative addition enthalpies obtained calorimetrically, it is possible to derive lower limits for the absolute exothermicities of H2 (48 kcal/mol) and CO (72 kcal/mol) addition to IrL*2Cl; estimates can also be made for the addition of benzene and acetylene C−H bonds. These values are unusually high; indeed, the magnitude of the Ir−CO BDE is unprecedented. In addition, kinetic methods have been used to determine a lower limit of 29 kcal/mol to the Rh−N2 BDE of RhL*2Cl(N2). Combined with previous calorimetric measurements on rhodium complexes, this value permits the calculation of lower limits to the absolute exothermicities of addition to RhL*2Cl for numerous small molecules including H2, CO, N2, C2H4, and aldehydic C−H bonds. The results of electronic structure calculations (approximate DFT; PMe3 used to model P i Pr3) are in excellent agreement with the relative experimental enthalpies, while the absolute values calculated for addition to IrL2Cl are significantly greater than the experimentally determined lower limits. Addition of a methane C−H bond is calculated to be significantly less favorable than addition of benzene or acetylene C−H bonds, in accord with the fact that IrL*2Cl(alkyl)H complexes have not been reported. The significant differences in the enthalpies of addition for these three types of C−H bonds are briefly analyzed.

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Thermodynamics of Addition of CO, Isocyanide, and H2 to Rh(PR3)2Cl

Wang¹,

Rosini²,

Nolan³

et al. 1995

J. Am. Chem. Soc.

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Glen P. Rosini

Thermochemical alkane dehydrogenation catalyzed in solution without the use of a hydrogen acceptor

Study of the Mechanism of Photochemical Carbonylation of Benzene Catalyzed by Rh(PMe3)2(CO)Cl

Photochemical C−H Activation and Ligand Exchange Reactions of CpRe(PPh₃)₂H₂. Phosphine Dissociation Is Not Involved

Thermodynamics of Addition of H₂, CO, N₂, and C−H Bonds to M(PⁱPr₃)₂Cl (M = Ir, Rh). An Unprecedented Metal−Carbonyl Bond Strength

Thermodynamics of Addition of CO, Isocyanide, and H2 to Rh(PR3)2Cl

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Glen P. Rosini

Thermochemical alkane dehydrogenation catalyzed in solution without the use of a hydrogen acceptor

Study of the Mechanism of Photochemical Carbonylation of Benzene Catalyzed by Rh(PMe3)2(CO)Cl

Photochemical C−H Activation and Ligand Exchange Reactions of CpRe(PPh3)2H2. Phosphine Dissociation Is Not Involved

Thermodynamics of Addition of H2, CO, N2, and C−H Bonds to M(PiPr3)2Cl (M = Ir, Rh). An Unprecedented Metal−Carbonyl Bond Strength

Thermodynamics of Addition of CO, Isocyanide, and H2 to Rh(PR3)2Cl

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Photochemical C−H Activation and Ligand Exchange Reactions of CpRe(PPh₃)₂H₂. Phosphine Dissociation Is Not Involved

Thermodynamics of Addition of H₂, CO, N₂, and C−H Bonds to M(PⁱPr₃)₂Cl (M = Ir, Rh). An Unprecedented Metal−Carbonyl Bond Strength