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Ethylene glycol is a commodity chemical with an annual consumption of 20 million tonnes. Its production generates 1.6 tonnes of CO2 per tonne of ethylene glycol. To reduce these CO2 emissions, the authors report a one-step electrochemical route to selectively convert ethylene to ethylene glycol at ambient temperature and pressure in aqueous media.
Identifying rate-determining steps (RDSs) is one of the most challenging aspects of catalysis. This work presents a general framework to identify the RDS of mixed ion and electron transfer reactions, and applies it to the four-electron/two-ion O2 reduction in solid-oxide fuel cell cathodes, converging on four RDS out of more than 100 possible candidates.
Late-stage aromatic chlorination of active pharmaceutical ingredients has enormous potential in drug discovery yet still features limited applicability due to issues of functional-group tolerance. Now, dimethyl sulfoxide is reported as catalyst for the chlorination of a diverse family of bioactive molecules in combination with N-chlorosuccinimide.
The rational design of catalysts is crucial to make power-to-X technologies viable. Here the authors introduce the delafossite PdCoO2 as a highly active hydrogen evolution reaction catalyst due to the growth of a tensile-strained Pd-rich capping layer under reductive conditions. Image credit: Christop Hohmann.
Electrocatalytic reduction of CO2 to multicarbon products is useful for producing high-value chemicals and fuels. Here the authors present a strategy that is based on the in situ electrodeposition of copper under CO2 reduction conditions that preferentially expose and maintain Cu(100) facets, which favour the formation of C2+ products.
In situ studies of catalytic surface reactions are restricted to a small number of analytical techniques. Here, scanning electron microscopy is utilized to visualize the catalytic hydrogenation of nitrogen dioxide on platinum, showing its potential for monitoring reaction dynamics on surfaces.
Electrochemical conversion of CO2 into liquid fuels, powered by renewable electricity, offers one means to address the need for the storage of intermittent renewable energy. Now, Sargent and co-workers present a cooperative catalyst design of molecule–metal interfaces to improve the electrosynthesis of ethanol from CO2 by producing a reaction-intermediate-rich local environment.
Enzyme engineering is opening up new chemistries. Here, the authors report enzymes engineered to contain two biological active sites — also showing that one site can be converted to a metal-complex catalyst — and demonstrate the utility of such dual sites in a range of catalytic processes.
Nickel complexes are of ever-increasing importance in organic synthesis; however, unstable Ni(COD)2 is still the main Ni(0) source used. Here the authors report a solution to this long-standing issue: an air stable Ni(0) complex that acts as a general precatalyst for numerous nickel-catalysed reactions.
Additions to alkenes and alkynes are useful routes for generating highly functionalized products. Here the authors report the 1,1-difunctionalization of alkynes through a CuH-catalysed asymmetric hydroboration/hydroamination cascade.
Methods to allow access to all isomers of a product are both valuable and challenging to achieve. Here the authors report a catalytic system comprised of an N-heterocyclic carbene and an iridium complex, and show that it can be used for the asymmetric, diastereodivergent synthesis of γ-butyrolactones.
The sugar d-apiose is important in plant cell wall polysaccharides. Here the authors elucidate the complex, multistep biosynthetic pathway for its production using enzyme crystal structures and computational analysis.
The synthesis of organophosphorus compounds from elemental phosphorus is an inefficient process, using multiple steps, stoichiometric metal complexes and/or hazardous reagents such as chlorine gas. Here, a direct photocatalytic route to convert white phosphorus (P4) into phosphines and phosphonium salts is reported.
The synthesis of chiral amines is of crucial importance for the pharmaceutical industry, but it remains a challenging task and is often inefficient. Now, a heterogeneous iridium complex is developed for the asymmetric hydrogenation of imines and the asymmetric reductive amination of carbonyl compounds in continuous flow with high yields and enantioselectivities.
The electrocatalytic upgrading of CO to higher-value feedstocks provides a promising route to multicarbon products. Here, the authors show that high ethylene selectivity can be achieved by constraining CO availability on copper, with an ethylene Faradaic efficiency of 72% and a partial current density of >800 mA cm−2.
The asymmetric hydrogenation of alkenes is a common route to optically active compounds, but alkene synthesis is often atom-inefficient, and the formation of isomers further complicates the procedure. Now the Ir-catalysed deoxygenation of racemic alcohols is shown to be a simple route to enantioenriched products.
Photocatalytic activation of alkyl carbon–chlorine bonds has constantly proven difficult due to the high energies needed to cleave this stable bond. Here a surfactant-based photocatalytic system is used, allowing for the radical dehalogenation and subsequent reactivity of unactivated alkyl chlorides.
Deuterated molecules are important both as labelled probes and as targets in their own right. Here the authors report a very simple and general deuteration of aldehydes, by the use of an N-heterocyclic carbene catalyst in the presence of D2O.
Due to its stability nitrogen is often employed as an inert gas during catalytic reactions. Now, a study shows that N2 can act as promoter for the catalytic hydrodeoxygenation of p-cresol on supported ruthenium catalysts through the formation of hydrogenated nitrogen species acting as a source of protic hydrogen.
This work shows that the biosynthesis of the polyether tetronasin involves an apparent enzyme-catalysed inverse-electron-demand hetero-Diels–Alder reaction to form an unexpected oxadecalin intermediate. A second enzyme then rearranges the oxadecalin to form the four-ringed tetronasin.