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Knots have been rigorously studied since the 1860s, but only in the past 30 years have they been made in the laboratory in molecular form. Now, the most complex small-molecule examples so far — a composite knot and an isomeric link, each with nine crossings — have been prepared.
The preparation of three-dimensional frameworks with multiple stereocentres from simple acyclic hydrocarbons represents a challenging transformation. Now, starting from simple and readily available reagents, formation of these complex targets can be achieved in just three catalytic transformations with high levels of stereocontrol.
New natural-product-inspired molecules are often limited by their only partial coverage of biologically relevant chemical space. Combining fragments of natural products has now been shown to yield pseudo natural products, which — while still being inspired by natural products — populate previously unexplored areas of chemical space and have novel biological activities.
The simplest sugar—glycolaldehyde—has recently been detected in space and now a mechanistic rationale for its formation is presented, which includes its onward reaction to the next higher aldose, glyceraldehyde. The key species in the chemistry at play is the formaldehyde isomer hydroxymethylene, which reacts with the carbonyl component in an essentially barrierless carbonyl–ene-type reaction.
Layered coordination polymers are attractive for the preparation of advanced 2D materials but they are typically non-magnetic insulators. Now such a layered network, CrCl2(pyrazine)2, has been prepared that comprises a paramagnetic metal ion and a redox-active ligand. The material exhibits both magnetism — with a ferrimagnetic ground state — and high electrical conductivity.
A composite knot with nine crossings of the same handedness has been prepared from a hexameric circular helicate in 41% yield in a two-step synthesis. An isomeric cyclic [3]catenane topologically constrained to always have at least three twists within the links is also formed. Both topologies have a high degree of writhe, analogous to that of supercoiled DNA.
Aryl functionalization of carbon nanotubes generates sp3 defects capable of quantum light emission. A multiplicity of possible binding configurations, however, leads to spectrally diverse emission bands. Now, it is shown that the structural symmetry of zigzag nanotubes and a high chemical selectivity for ortho configurations results in defect-state emission from a single narrow band.
Dynamic covalent chemistry offers promise for the formation of elaborate extended network materials in high yields, but the limited number of reactions available confines the scope and functionality of the materials synthesized. Now, nucleophilic aromatic substitution has been shown to be reversible, and thus self-correcting, enabling the easy synthesis of sulfur-rich materials.
In solid metals, electron orbitals form broad bands and their binding of adsorbates depends on the bandwidth. Now, it is shown that a weak solute–matrix interaction in dilute alloys results in extremely narrow electronic bands on the solute, similar to a free-atom electronic structure. This structure affords unique adsorption properties important for catalysis.
Surface engineering is an attractive route to tune the processability, stability and functionalities of 2D materials, but typically introduces defects in the resulting structures. Now, the issue has been circumvented through pre-synthetic functionalization instead; an isoreticular family of robust layered coordination polymers has been mechanically exfoliated to give functionalized crystalline magnetic monolayers.
A rapid, modular, stereodivergent and diversity-oriented strategy for constructing acyclic molecular frameworks bearing up to four contiguous and congested stereogenic elements has been developed. This approach can yield the target compounds with remarkably high levels of stereocontrol in only three catalytic steps from commercially available alkynes.
Measurements of vector correlations provide insight into the forces acting during molecular collisions, and are a stringent test of electronic-structure calculations. Now, non-intuitive dynamics of molecular collisions have been revealed by measuring the correlation between the relative velocities of the colliders and the molecular rotational angular momentum—before and after the collision—for NO(A 2Σ+) + Ne.
On-surface polymerization is a promising technique to prepare organic functional nanomaterials, but it has remained difficult to carry out on insulating surfaces. Now, the photoinitiated radical polymerization of dimaleimide on KCl, initiated from a two-dimensional gas phase and guided by molecule–substrate interactions, has led to polymer fibres up to 1 μm long.
Lipid membranes—which separate cells and organelles from their environment—experience tension during various cell processes; however, measuring membrane tension is notoriously difficult. Now, a new fluorescent, mechanosensitive membrane probe called FliptR has been developed. FliptR enables simple, direct membrane tension measurements in cellular and artificial membranes.
State-of-the-art quantum simulations predict that solvent molecules may partner with a solute in solution to form stable chemically distinct coordination species that interconvert from one to another. The solvent would thus be directly implicated in chemical reactions.
Specific forms of nitrogen doping can endow carbon-based metal-free materials with electrocatalytic activity. Now, introducing sp-hybridized nitrogen atoms into some acetylenic sites of ultra-thin graphdiyne — a highly π-conjugated lamellar carbon allotrope — has led to excellent oxygen reduction reaction activity.
Organoclay/DNA semipermeable microcapsules with catalase-powered oxygen gas bubble-dependent buoyancy are prepared and exploited as synthetic protocells capable of programmed motility and sustained oscillatory movement.
Traditionally, strong-bond activation by transition metals has been achieved through an oxidative addition pathway. Now, a redox-neutral palladium(ii)-catalysed β-elimination strategy has been shown to activate alkyl C–O, N, C, F and S bonds to give an alkene that can be trapped with various nucleophiles. This functional group metathesis allows upgrading of amino acid derivatives and ring-opening of saturated heterocycles.