Molecular Electrocatalytic Hydrogenation of Carbonyls and Dehydrogenation of Alcohols

Wolff, Niklas von; Rivada‐Wheelaghan, Orestes; Tocqueville, Damien

doi:10.1002/celc.202100617

Cited by 21 publications

(24 citation statements)

References 104 publications

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“…Molecular catalysts for electrochemical alcohol oxidation have been reviewed recently. [17][18][19] Here, we focus on a subset of catalysts for which electrochemical two-electron oxidation of alcohols was performed in THF or MeCN using bases with known pK a values, which allows the determination of overpotentials (Figure 5 and Table 2). As discussed in the previous section, catalyst performance should be evaluated under buffered conditions.…”

Section: Evaluation Of Overpotential For Known Electrocatalysts For O...mentioning

confidence: 99%

Determining overpotentials for the oxidation of alcohols by molecular electrocatalysts in non-aqueous solvents

Speelman

Gerken

Heins

et al. 2022

Energy Environ. Sci.

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Section: Evaluation Of Overpotential For Known Electrocatalysts For O...mentioning

confidence: 99%

Determining overpotentials for the oxidation of alcohols by molecular electrocatalysts in non-aqueous solvents

Speelman

Gerken

Heins

et al. 2022

Energy Environ. Sci.

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“…Another important challenge is here to reduce the carbonyl to the alcohol in a chemoselective way, avoiding the ketyl radical coupling and the hydrogenation of other unsaturations (e.g., C=C) when present ( Figure 5 b). 48 , 49 To drive carbonyl hydrogenation to the desired selectivity, molecular electrocatalysts have been investigated, 50 , 51 mostly based on Ni, 52 , 53 Fe, 52 , 53 Ru, 54 and Rh 55 − 57 metal complexes, with a body of work using homogeneous and immobilized Rh bipyridine type complexes. 55 − 57 …”

Section: Case Studiesmentioning

confidence: 99%

Electrocatalysis with Molecular Transition-Metal Complexes for Reductive Organic Synthesis

Kaeffer

Leitner

2022

JACS Au

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Electrocatalysis enables the formation or cleavage of chemical bonds by a genuine use of electrons or holes from an electrical energy input. As such, electrocatalysis offers resource-economical alternative pathways that bypass sacrificial, waste-generating reagents often required in classical thermal redox reactions. In this Perspective, we showcase the exploitation of molecular electrocatalysts for electrosynthesis, in particular for reductive conversion of organic substrates. Selected case studies illustrate that efficient molecular electrocatalysts not only are appropriate redox shuttles but also embrace the features of organometallic catalysis to facilitate and control chemical steps. From these examples, guidelines are proposed for the design of molecular electrocatalysts suited to the reduction of organic substrates. We finally expose opportunities brought by catalyzed electrosynthesis to functionalize organic backbones, namely using sustainable building blocks.

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“…The selective electrochemical reduction of polar CO moieties catalyzed by transition metal complexes is still largely underexplored . In radical-type reductions that proceed via 1H + /1e – steps, the initially formed XH bond is very weak, which necessitates the use of catalysts with a low bond dissociation free energy (BDFE).…”

Section: Introductionmentioning

confidence: 99%

Electroreduction of Carbonyl Compounds Catalyzed by a Manganese Complex

2022

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Chemical conversions are nowadays evaluated not only according to their functionality and originality but also regarding their atom and redox economy. Excess energy consumption, the origin of that energy, and waste production are becoming increasingly important factors in chemical synthesis development. This led to a re-emerging of electroorganic synthesis after decades of dormancy. Inspired by this, we combined organometallic catalysis and electrochemistry to develop a versatile and broadly applicable method for hydrogenation of ketones and aldehydes by electrons and trifluoroethanol as proton source under ambient conditions. Aromatic, aliphatic, and further functionalized ketones and aldehydes were converted to the corresponding alcohols in decent to excellent yields, with a catalyst loading of only 1%. The protocol is selective toward ketones and aldehydes over non-conjugated CC bonds, esters, and carboxylic acids. As a base metal catalyst, we utilized a manganese complex with a proton relay, which was previously shown to electrohydrogenate CO2 via an Mn–H species. Mechanistic analysis showed that this hydride is also pivotal for the electrohydrogenation of CO bonds in organic scaffolds and fosters ionic hydrogenations over radical-type PCET reactions, which leads to the observed selectivity toward polar substrates. Further mechanistic analysis shed light on the pK a of the metal hydride species, the kinetic rate of its formation, as well as the all-over catalysis. Chemical formation of the MnH species via H2 splitting under ambient conditions failed, which emphasizes that merging electrochemistry and organometallic catalysis can open different pathways for chemical catalysis under mild conditions.

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Molecular Electrocatalytic Hydrogenation of Carbonyls and Dehydrogenation of Alcohols

Cited by 21 publications

References 104 publications

Determining overpotentials for the oxidation of alcohols by molecular electrocatalysts in non-aqueous solvents

Determining overpotentials for the oxidation of alcohols by molecular electrocatalysts in non-aqueous solvents

Electrocatalysis with Molecular Transition-Metal Complexes for Reductive Organic Synthesis

Electroreduction of Carbonyl Compounds Catalyzed by a Manganese Complex

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