Examining the Modular Synthesis of [Cp*Rh] Monohydrides Supported by Chelating Diphosphine Ligands

Comadoll, Chelsea G.; Henke, Wade C.; Leseberg, Julie Hopkins; Douglas, Justin T.; Oliver, Allen G.; Day, Victor W.; Blakemore, James D.

doi:10.1021/acs.organomet.1c00525

Cited by 12 publications

(20 citation statements)

References 65 publications

(74 reference statements)

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“…[36] To confirm our assignment of these resonances, we carried out multifrequency NMR experiments at 400, 500, 600, and 800 MHz that confirm the involvement of second-order effects which are visible in the spectra as "roofing". [37,38] Digital simulations of the field-dependent spectra reproduced the experimental data, confirming our assignment (Figure S26).…”

Section: Chemistry-a European Journalsupporting

confidence: 83%

Evidence for Charge Delocalization in Diazafluorene Ligands Supporting Low‐Valent [Cp*Rh] Complexes**

Henke

Stiel

Day

et al. 2022

Chemistry A European J

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Ligands based upon the 4,5-diazafluorene core are an important class of emerging ligands in organometallic chemistry, but the structure and electronic properties of these ligands have received less attention than they deserve. Here, we show that 9,9′-dimethyl-4,5-diazafluorene (Me2daf) can stabilize low-valent complexes through charge delocalization into its conjugated π-system. Using a new platform of [Cp*Rh] complexes with three accessible formal oxidation states (+III, +II, and +I), we show that the methylation in Me2daf is protective, blocking Brønsted acid-base chemistry commonly encountered with other daf-based ligands. Electronic absorption spectroscopy and single-crystal X-ray diffraction analysis of a family of eleven new compounds, including the unusual Cp*Rh(Me2daf), reveal features consistent with charge delocalization driven by π-backbonding into the LUMO of Me2daf, reminiscent of behavior displayed by the workhorse 2,2′-bipyridyl ligand. Taken together with spectrochemical data demonstrating clean conversion between oxidation states, our findings show that 9,9′-dialkylated daf-type ligands are promising building blocks for applications in reductive chemistry and catalysis.

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Section: Chemistry-a European Journalsupporting

confidence: 83%

Evidence for Charge Delocalization in Diazafluorene Ligands Supporting Low‐Valent [Cp*Rh] Complexes**

Henke

Stiel

Day

et al. 2022

Chemistry A European J

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“…Eager to further interrogate this species, we repeated this protonation experiment with IR monitoring, providing unequivocal evidence from vibrational data for the formation of [Cp*Rh(H)(bpy)] + (4) based on a characteristic Rh-H stretch at 1920 cm -1 (Figure 5). Notably, this value is similar to other Rh-H stretches (1986-1936 cm -1 ) previously reported by our group for analogous [Cp*Rh] monohydride complexes ligated by bisphosphine ligands, albeit slightly lower in energy, and is in good agreement with our DFT-calculated spectrum (1920 vs 1902 cm -1 , respectively, see SI, Figure S32) (24,26). The UV-vis spectrum of 4 displays a prominent absorption at 400 nm and weaker features that tail into the visible region.…”

Section: Initial Proton Transfer and Tautomerizationsupporting

confidence: 92%

“…To this point, 3 exhibits vivid pigmentation, attributable to delocalization of electron density by π-backbonding into the bpy π-system (45). The properties of bpy thus strongly influence the catalytic reactivity paradigm observed, reactivity that is not echoed in systems supported by bidentate bisphosphine ligands (24,26) or even the closely related 9,9′-dimethyl-4,5diazafluorene ligand (43), as well as impart spectral uniqueness to the [Cp*Rh] system.…”

Section: Discussionmentioning

confidence: 99%

“…Despite attempts, the putative [Cp*Rh-H] intermediate has only been observed in mixtures of products that are generated under very specific reaction conditions involving, variously, photochemical reactors, buffered solutions, or low temperatures (-40°C) (12,23). On the other hand, our group has recently developed reliable synthetic procedures to access analogous phosphine-supported [Cp*Rh] monohydrides, but these species are remarkably resistant to protonolysis due to enhanced stabilization provided by phosphine ligands (24,25,26). Contrasting with these monohydrides, isolated [(Cp*H)Rh(bpy)] + reacts with even moderate acids such as anilinium ([PhNH3] + , pKa = 10.6 in MeCN) to quantitatively yield H2 and regenerate the starting Rh(III) complex (18).…”

mentioning

confidence: 99%

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Mechanistic Roles of Metal- and Ligand-Protonated Species in Hydrogen Evolution with [Cp*Rh] Complexes

Henke

Peng

Meier

et al. 2022

Preprint

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Protonation reactions involving organometallic complexes are ubiquitous in redox chemistry and often result in the generation of reactive metal hydrides. However, some organometallic species supported by η5-pentamethylcyclopentadienyl (Cp*) ligands have recently been shown to undergo ligand-centered protonation by direct proton transfer from acids or tautomerization of metal hydrides, resulting in the generation of complexes bearing the uncommon η4-cyclopentadiene (Cp*H) ligand. Here, time-resolved pulse radiolysis (PR) and stopped-flow spectroscopic studies have been applied to examine the kinetics and atomistic details involved in the elementary electron- and proton-transfer steps leading to complexes ligated by Cp*H, using Cp*Rh(bpy) as a molecular model (where bpy is 2,2′-bipyridyl). Stopped-flow measurements coupled with infrared and UV-visible detection reveal that the sole product of initial protonation of Cp*Rh(bpy) is [Cp*Rh(H)(bpy)]+, an elusive hydride complex that has spectroscopically and kinetically characterized here for the first time. Tautomerization of the hydride leads to the clean formation of [(Cp*H)Rh(bpy)]+. Variable-temperature and isotopic labeling experiments further confirm this assignment, providing experimental activation parameters and mechanistic insight into metal-mediated hydride-to-proton tautomerism. Spectroscopic monitoring of the second proton transfer event reveals both the hydride and related Cp*H complex can be involved in further reactivity, showing that [(Cp*H)Rh] is not necessarily an off-cycle intermediate, but, instead, depending on the strength of the acid used to drive catalysis, an active participant in hydrogen evolution. Identification of the mechanistic roles of the protonated intermediates in the catalysis studied here will inform design of new catalytic systems supported by non-innocent cyclopentadienyl-type ligands.

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“…Generally, reduction of NAD + can be conducted by chemical, − photochemical, − enzymatic, − and electrochemical means. − To be specific, vast development in the field of organometallic chemistry cultivated numerous chemical regeneration catalysts including organometallic complexes of ruthenium, iridium, − and rhodium. , Rhodium complexes, in particular, feature improved 1,4-regioselectivity, high stability, and very good activity, making rhodium-incorporated organometallic catalysts the best prospects. − The main drawbacks of hitherto presented rhodium complexes are, however, their low TOFs and a consequent increase in the concentration of added catalyst. , In order to overcome the shortcomings, improved activity of the catalyst is necessary . Extensive research has been done to address the issue, and this led to isolation of the first catalytic intermediate of [Cp*Rh(bpy)Cl] + with a Cp*–H fragment, (Cp*H)Rh(bpy)Cl. , Furthermore, recent studies on rhodium complexes with phosphine-containing ligands reported the isolation of stable rhodium hydride complexes. − However, these findings opened a new debate regarding the structure of the intermediate through which the hydride is transferred to NAD + , either directly via a Rh–H intermediate or by its equilibrium tautomer with a η 4 -Cp*H moiety. Previous studies show that, to achieve a fast intermediate generation, increased electron density on the metal center with more electron-donating ligand systems is essential. , Yet, the relationship between the reaction rate and the form of the intermediate has not been intensely scrutinized.…”

Section: Introductionmentioning

confidence: 99%

Efficient Nicotinamide Adenine Dinucleotide Regeneration with a Rhodium–Carbene Catalyst and Isolation of a Hydride Intermediate

et al. 2022

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Regeneration of nicotinamide adenine dinucleotide (NADH) has been the primary interest in the field of enzymatic transformation, especially associating oxidoreductases given the stoichiometric consumption. The synthesized carbene-ligated rhodium complex [(η 5 -Cp*)Rh(MDI)Cl] + [Cp* = pentamethylcyclopentadienyl; MDI = 1,1′-methylenebis(3,3′-dimethylimidazolium)] acts as an exceptional catalyst in the reduction of NAD + to NADH with a turnover frequency of 1730 h −1 , which is over twice that of the higher catalytic activity of the commercially available catalyst [Cp*Rh(bpy)Cl] + (bpy = 2,2'-bipyridine). Offsetting the contentious atmosphere currently taking place over the specific intermediate of the NADH regeneration, this study presents pivotal evidence of a metal hydride intermediate with a bis(carbene) ligand: a stable form of the rhodium hydride intermediate, [(η 5 -Cp*)Rh(MDI)H] + , was isolated and fully characterized. This enables thorough insight into the possible mechanism and exact intermediate structure in the NAD + reduction process.

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Examining the Modular Synthesis of [Cp*Rh] Monohydrides Supported by Chelating Diphosphine Ligands

Cited by 12 publications

References 65 publications

Evidence for Charge Delocalization in Diazafluorene Ligands Supporting Low‐Valent [Cp*Rh] Complexes**

Evidence for Charge Delocalization in Diazafluorene Ligands Supporting Low‐Valent [Cp*Rh] Complexes**

Mechanistic Roles of Metal- and Ligand-Protonated Species in Hydrogen Evolution with [Cp*Rh] Complexes

Efficient Nicotinamide Adenine Dinucleotide Regeneration with a Rhodium–Carbene Catalyst and Isolation of a Hydride Intermediate

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