Caroline T. Saouma scite author profile

Mid-to-late transition metal complexes that feature terminal, multiply bonded ligands such as oxos, imides, and nitrides have been invoked as intermediates in several catalytic transformations of synthetic and biological significance. Until about ten years ago, isolable examples of such species were virtually unknown. Over the past decade or so, numerous chemically well-defined examples of such species have been discovered. In this context, the presentreview summarizes the development of 4- and 5-coordinate Fe(E) and Co(E) species under local three-fold symmetry.

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Thermodynamic Analysis of Metal–Ligand Cooperativity of PNP Ru Complexes: Implications for CO₂ Hydrogenation to Methanol and Catalyst Inhibition

Mathis

et al. 2019

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The hydrogenation of CO 2 in the presence of amines to formate, formamides, and methanol (MeOH) is a promising approach to streamlining carbon capture and recycling. To achieve this, understanding how catalyst design impacts selectivity and performance is critical. Herein we describe a thorough thermochemical analysis of the (de)hydrogenation catalyst, (PNP)Ru−Cl (PNP = 2,6-bis(di-tertbutylphosphinomethyl)pyridine; Ru = Ru(CO)(H)) and correlate our findings to catalyst performance. Although this catalyst is known to hydrogenate CO 2 to formate with a mild base, we show that MeOH is produced when using a strong base. Consistent with pK a measurements, the requirement for a strong base suggests that the deprotonation of a sixcoordinate Ru species is integral to the catalytic cycle that produces MeOH. Our studies also indicate that the concentration of MeOH produced is independent of catalyst concentration, consistent with a deactivation pathway that is dependent on methanol concentration, not equivalency. Our temperature-dependent equilibrium studies of the dearomatized congener, (*PNP)Ru, with various H−X species (to give (PNP)Ru−X; X = H, OH, OMe, OCHO, OC(O)NMe 2 ) reveal that formic acid equilibrium is approximately temperature-independent; relative to H 2 , it is more favored at elevated temperatures. We also measure the hydricity of (PNP)Ru−H in THF and show how subsequent coordination of the substrate can impact the apparent hydricity. The implications of this work are broadly applicable to hydrogenation and dehydrogenation catalysis and, in particular, to those that can undergo metal−ligand cooperativity (MLC) at the catalyst. These results serve to benchmark future studies by allowing comparisons to be made among catalysts and will positively impact rational catalyst design.

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Do spin state and spin density affect hydrogen atom transfer reactivity?

2014

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The prevalence of hydrogen atom transfer (HAT) reactions in chemical and biological systems has prompted much interest in establishing and understanding the underlying factors that enable this reactivity. Arguments have been advanced that the electronic spin state of the abstractor and/or the spin-density at the abstracting atom are critical for HAT reactivity. This is consistent with the intuition derived from introductory organic chemistry courses. Herein we present an alternative view on the role of spin state and spin-density in HAT reactions. After a brief introduction, the second section introduces a new and simple fundamental kinetic analysis, which shows that unpaired spin cannot be the dominant effect. The third section examines published computational studies of HAT reactions, which indicates that the spin state affects these reactions indirectly, primarily via changes in driving force. The essay concludes with a broader view of HAT reactivity, including indirect effects of spin and other properties on reactivity. It is suggested that some of the controversy in this area may arise from the diversity of HAT reactions and their overlap with proton-coupled electron transfer (PCET) reactions.

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Toward Combined Carbon Capture and Recycling: Addition of an Amine Alters Product Selectivity from CO to Formic Acid in Manganese Catalyzed Reduction of CO₂

et al. 2020

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Owing to the energetic cost associated with CO 2 release in carbon capture (CC), the combination of carbon capture and recycling (CCR) is an emerging area of research. In this approach, "captured CO 2 ," typically generated by addition of amines, serves as a substrate for subsequent reduction. Herein, we report that the reduction of CO 2 in the presence of morpholine (generating mixtures of the corresponding carbamate and carbamic acid) with a well-established Mn electrocatalyst changes the product selectivity from CO to H 2 and formate. The change in selectivity is attributed to in situ generation of the morpholinium carbamic acid, which is sufficiently acidic to protonate the reduced Mn species and generate an intermediate Mn hydride. Thermodynamic studies indicate that the hydride is not sufficiently hydritic to reduce CO 2 to formate, unless the apparent hydricity, which encompasses formate binding to the Mn, is considered. Increasing steric bulk around the Mn shuts down rapid homolytic H 2 evolution rendering the intermediate Mn hydride more stable; subsequent CO 2 insertion appears to be faster than heterolytic H 2 production. A comprehensive mechanistic scheme is proposed that illustrates how thermodynamic analysis can provide further insight. Relevant to a range of hydrogenations and reductions is the modulation of the hydricity with substrate binding that makes the reaction favorable. Significantly, this work illustrates a new role for amines in CO 2 reduction: changing the product selectivity; this is pertinent more broadly to advancing CCR.

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Fe(I)-Mediated Reductive Cleavage and Coupling of CO₂: An Fe^II(μ-O,μ-CO)Fe^II Core

et al. 2006

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THF solutions of a new iron(I) source, "[PhBP CH2Cy 3 ]Fe" ([PhBP CH2Cy 3 ] = [PhBP(CH 2 P (CH 2 Cy) 2 ) 3 ] − ), effect the reductive cleavage of CO 2 via O-atom transfer at ambient temperature. The dominant reaction pathway is bimetallic and leads to the formation of a structurally unprecedented diiron Fe II (μ-O)(μ-CO)Fe II core. X-ray data are also available to suggest that bimetallic reductive CO 2 coupling to generate oxalate occurs as a minor reaction pathway. These initial observations forecast a diverse reaction landscape between CO 2 and iron (I) synthons.Direct O-atom transfer from CO 2 is a difficult transformation to realize given the molecule's thermodynamic and kinetic stability. Highly reducing early transition, lanthanide, and actinide metal complexes are known that facilitate reductive C-O cleavage of CO 2 . 1 Later first row ions, while active for CO 2 binding, do not typically display similar cleavage transformations. 2 ,3 Nature, however, is presumed to exploit low-valent, later first row metal ions (e.g., Ni, Fe) to mediate CO 2 reduction/CO oxidation in the C cluster of CODH enzymes. 4

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