Abstract
Carboxylic acids are ubiquitous in bio-renewable and petrochemical sources of carbon. Hydrogenation of carboxylic acids to yield alcohols produces water as the only byproduct, and thus represents a possible next generation, sustainable method for the production of these alternative energy carriers/platform chemicals on a large scale. Reported herein are molecular insights into cationic mononuclear ruthenium carboxylates ([Ru(OCOR)]+) as prototypical catalysts for the hydrogenation of carboxylic acids. The substrate-derived coordinated carboxylate was found to function initially as a proton acceptor for the heterolytic cleavage of dihydrogen, and subsequently also as an acceptor for the hydride from [Ru–H]+, which was generated in the first step (self-induced catalysis). The hydrogenation proceeded selectively and at high levels of functional group tolerance, a feature that is challenging to achieve with existing heterogeneous/homogeneous catalyst systems. These fundamental insights are expected to significantly benefit the future development of metal carboxylate-catalysed hydrogenation processes of bio-renewable resources.
Highlights
Carboxylic acids are ubiquitous in bio-renewable and petrochemical sources of carbon
The carboxylic acids (CAs)-derived carboxylate coordinated to the Ru centre was found to function initially as a proton acceptor in the heterolytic cleavage of dihydrogen, and subsequently as a acceptor for a hydride from [Ru–H] þ, which was generated in the first step
The hydrogenation of esters is not promoted, and this catalytic system constitutes a benchmark achievement that may be potentially useful for selective organic synthesis and for the development of future catalytic hydrogenation methods for feedstock derived from biomass or CO2
Summary
Carboxylic acids are ubiquitous in bio-renewable and petrochemical sources of carbon. 3-phenylpropionic acid (CA-a; Table 1, entry 1) in toluene using a combination of Ru-a (2 mol%: [Ru]0 1⁄4 6.7 mM), NaBPh4 (10 mol%), and high pressure of H2 (PH2 1⁄4 8 MPa, T 1⁄4 160 °C, t 1⁄4 24 h) resulted in the formation of alcohol AL-a and the ester
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