Reviews & Analysis

Introducing C–F bonds into organic molecules is a challenging task, particularly through C–H activation methods. Now, a uranium-based photocatalyst turns traditional selectivity rules on their heads and fluorinates unfunctionalized alkane Csp³–H bonds, even in the presence of C–H bonds that are typically more reactive.

An artificial esterase with no known natural structural analogues has been formed via the homo-heptameric self-assembly of a designed peptide. This esterase represents the first report of a functional catalytic triad rationally engineered into a de novo protein framework.

Density functional theory calculations can be carried out with different levels of accuracy, forming a hierarchy that is often represented by the rungs of a ladder. Now a new method has been developed that significantly improves the accuracy of the 'third rung' when calculating the properties of diversely bonded systems.

Chemists have long been fascinated by electron delocalization, from both a fundamental and applied perspective. Macrocyclic oligomers containing fused ferrocenes provide a new structural framework — containing strongly interacting metal centres — that is capable of supporting substantial charge delocalization.

The slow kinetics of light-driven water oxidation on haematite is an important factor limiting the material's efficiency. Now, an intermediate of the water-splitting reaction has been identified offering hope that the full mechanism will soon be resolved.

Carbonyls and alkenes, two of the most common functional groups in organic chemistry, generally do not react with one another. Now, a simple Lewis acid has been shown to catalyse metathesis between alkenes and ketones in a new carbonyl olefination reaction.

A quantitative understanding of the functional landscape of a biochemical circuit can reveal the design rules required to optimize the circuit. Now, a high-throughput droplet-based microfluidic platform has been developed which enables high-resolution mapping of bifurcation diagrams for two nonlinear DNA networks.

The calcination of metal–organic framework (MOF) precursors is promising for the preparation of nanoscale carbon materials, but the resulting morphologies have remained limited. Now, controlling the growth of precursor MOFs has enabled 1D carbon nanorods to be fabricated — these can then be readily unravelled into 2D graphene nanoribbons.

Combining conventional transition-metal oxidation with oxygen oxidation in 'lithium-excess' materials is a recently discovered route to improving the capacity of lithium-ion batteries. Now two studies, one experimental and one theoretical, have investigated the processes, states and structures involved.

Nitric oxide (NO) has important functions in all forms of life and serves, for example, as a signalling molecule in mammals. Now, two complementary studies have uncovered how NO binds to blue copper proteins. This research suggests a mechanism by which NO could regulate the activity of blue copper proteins involved in denitrification.

Numerous dynamic molecular crystals whose physical properties can be switched by external stimuli have recently been developed. This Review discusses how the precise control of the electron, proton and molecular movement within the crystals through the application of external stimuli can lead to considerable changes in their properties.

Self-sorting events in supramolecular assembly lead to complex systems that are attractive for the design of functional materials, but have remained difficult to understand and control. Now, the growth of self-sorted supramolecular nanofibres has been elucidated by direct imaging through real-time in situ confocal microscopy.

The critical step in water splitting is the formation of a peroxo bond; the mechanism, thought to involve oxyl radical formation, remains elusive. Now, experiments reveal a distinct bond vibration directly connected to an oxyl radical that is simultaneously coupled to both the semiconductor electronic states and the motion of the surrounding water.

The low-complexity-protein, liquid phases of membraneless organelles have now been established to selectively partition biomolecules. The specialized microenvironment that they provide differs chemically from the surrounding medium and enables specific nucleic-acid remodelling reactions.

Early theories suggested the possibility of atomically thin boron layers, but electron-deficient boron favours multicentre bonds and assembles into various polymorphs, making the synthesis of such layers challenging. Now, in two independent experiments, the deposition of atomic boron has offered this long-sought material on a silver platter.

Natural products are a prime source of innovative molecular fragments and privileged scaffolds for drug discovery and chemical biology. Advanced machine-learning approaches can help analyse and design synthetically accessible, natural-product-derived, compound libraries and provide insight into the high selectivity of such compounds.

Understanding the minute details of CO₂ transport is key to finding new technologies that reduce the hazardous levels of CO₂ in our atmosphere. Now, the observation that the transport of CO₂ in molten calcium carbonate occurs faster than standard molecular diffusion brings us one step closer.

A fundamental challenge in systems chemistry is to engineer the emergence of complex behaviour. The collective structures of metal cyanide chains have now been interpreted in the same manner as the myriad of magnetic phases displayed by frustrated spin systems, highlighting a symbiotic approach between systems chemistry and magnetism.