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The use of gaseous sulfuryl fluoride in sulfur(VI) fluoride exchange reactions is a challenge. Now, a flow set-up for the on-demand generation and onward reaction of sulfuryl fluoride, from sulfuryl chloride, is reported. The process produces fluorosulfate and sulfamoyl fluoride analogues of small molecules, peptides and proteins.
Water electrolysis can produce clean hydrogen, but it is limited by the slow anodic oxygen evolution reaction. Now, a local electronic manipulation strategy for stabilizing high-valence Ru single site catalysts has been developed. The catalyst demonstrates efficient bifunctional activity for water electrolysis.
Controlling the reaction pathway in electrochemical CO2 reduction for the selective production of hydrocarbons or oxygenates is challenging. Now, control over atomic immiscibility in Cu and Cu–Ag alloyed catalysts can steer CO2 reduction products from ethylene towards ethanol.
Cation–anion exchange between dimers to prepare mixed aggregates with Mg–Ae (alkaline earth) bonding (Ae = Mg, Ca, Sr, Ba) is reported. Considerable electron transfer from the (BDI)Mgˉ anion (BDI, β-diketiminate) to Ae and Na atoms is observed, and the reactivity of these electron-rich complexes with Na–Mg–Ae bonding is discussed.
Nimbolide is an inhibitor of poly(ADP)-ribosylation-dependent ubiquitin E3 ligase RNF114. A modular synthesis of nimbolide and its analogues is now reported, using a sulfonyl hydrazone-mediated etherification and a radical cyclization strategy. These analogues give insight into structure–activity relationships and some have superior poly(ADP-ribose) polymerase-1 trapping activity relative to nimbolide.
The unexpected phenomenon of rapid, long-distance transport of an ultrathin and uniform metal film on two-dimensional crystals is reported at temperatures well below the melting points of all of the materials involved. The effect is generalizable and may offer possibilities in confined space chemistry, as well as in two-dimensional crystal growth and devices.
A flow microreactor-enabled method is reported for the stereo- and regioselective synthesis of multisubstituted alkenes by reductive syn-boryllithiation and syn-borylsodiation of arylacetylenes. Reaction of the alkyne substrate with a naphthalenide reductant and a boron electrophile generates a syn-β-borylalkenyl alkali metal intermediate, which can react with a range of electrophiles.
Sustained Mars exploration requires in situ synthesis of vital chemicals such as oxygen. Now a data-driven platform for synthesizing oxygen-producing electrocatalysts from Martian meteorites using robotics and artificial intelligence is developed, allowing automated screening of the optimal catalyst formula. This approach demonstrates materials discovery under challenging circumstances and without human intervention.
The chemical synthesis of jasmonates is typically low yielding and can be laborious, whereas their extraction can be costly or environmentally hazardous. Now a de novo biosynthesis of jasmonic acid and its derivatives, methyl jasmonate and jasmonoyl isoleucine, is reported, using an engineered baker’s yeast.
Mathematical functions can be found throughout nature and have importance for studying the assembly of single particles into branched superstructures. Here, Wedderburn–Etherington number patterns are produced in branched mesoporous silica nanotrees.
Strained cyclic allenes are short-lived intermediates that confine a functional group with a preferred linear geometry, an allene, into a small ring, inducing strain-driven reactivity. Now, 2,3-azacyclic and 2,3-oxacyclic allenes are generated and trapped using cycloaddition reactions, generating complex heterocycles that bear a large fraction of sp3-hybridized atoms.
Enantioselective γ-lactonization of unactivated C(sp3)–H bonds is a challenge using chemical methods. Now the biocatalytic enantioselective synthesis of γ-lactones from aliphatic carboxylic acids is reported, using a reengineered fatty acid hydroxylase, P450BSβ. Crystallographic and computational analyses show the observed γ-regioselectivity arises from the mutants introduced into P450BSβ.
Biocatalytic strategies typically transform only one alkene isomer into products, limiting the yield. Now a biocatalyst is reported to convert both isomeric silyl enol ethers into chiral α-branched ketones with high efficiency and excellent selectivity.
Arabinogalactan RN1 displays potent anti-pancreatic-cancer activity; however, the structure–activity relationship of RN1 is unclear. Now the synthesis of RN1 and a library of glycans are reported, using an iterative preactivation-based one-pot glycosylation strategy. Biological analysis reveals that a decasaccharide is the active structural domain of RN1.
Synthesizing phase-pure, higher-quantum-well thickness (n) 2D halide perovskites is challenging. Now, a general method, termed kinetically controlled space confinement, to synthesize 2D perovskites is reported. Transformation from low n-values to high n-values is achieved by tuning the temperature or time of crystallization.
β-Lactone-containing natural products are rare. Now, a polyketide with a unique cyclopentane–β-lactone skeleton is reported. The key enzymes identified for the formation of the bicyclic core are a non-ribosomal peptide synthetase-like module with a β-lactone ring forming esterase and peptidyl carrier protein, thioester reductase and condensation domains.
Unravelling the formation of binary nanocrystal phases is challenging. Here, by combining in situ small-angle X-ray scattering and molecular dynamics simulations, we show that AlB2 and NaZn13 superlattices undergo classical homogeneous nucleation consistent with the presence of short-range attractive interactions guiding the crystallization process.
In this approach, metal–organic framework (MOF) glasses are synthesized by the desolvation of mononuclear metal complexes. The MOF glasses are composed of transition metals and either carboxylate, pyridyl or azolate ligands. Their porous structures and formation of monoliths are regulated in this process.
High-entropy alloys (HEAs) have interesting properties, but the synthesis of uniform HEAs is challenging. Here design principles are established for the synthesis of core–shell nanoparticles, which can be thermally annealed to produce uniform HEA nanoparticles in a predictable manner.
The selective synthesis of non-symmetrical diamides and amido-esters is a challenge. Now a Pd-catalysed dicarbonylation method is reported that generates non-symmetrical diamides and amido-esters through diamino- and amino-alkoxy carbonylations of propargylic acetates using two different nucleophiles. Mechanistic studies reveal that the process occurs through a sequential carbonylation process.