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Direct enantioselective α-C(sp³)–H functionalization of Lewis-basic N-alkyl anilines has remained a significant challenge in synthetic chemistry. Now it has been shown that a metallaphotoredox-catalysed radical approach, with a sterically hindered aryl ketone photocatalyst, enables site-selective, enantioselective (hetero)arylation with exceptional functional group tolerance.

Electrochemical ammonia (NH₃) synthesis is a promising alternative to the Haber–Bosch process, but higher-performing systems are needed. Now, researchers realize long-term continuous NH₃ electrosynthesis and production of high fractions of gas-phase NH₃ by employing a chain ether as solvent, marking an important practical step forward.

Analysis of dendrite initiation, owing to filling of pores with lithium by means of microcracks, and propagation, caused by wedge opening, shows that there are two separate processes during dendrite failure of lithium metal solid-state batteries.

A three-dimensional continuous rotation electron diffraction method allows atomistic characterization of the chemistry of curved layered cathode materials.

The implementation of asymmetric Heck/cross coupling cascades of highly flexible haloalkene substrates remains a challenging and long-standing goal. Here the authors report an asymmetric domino Heck/Tsuji−Trost reaction of flexible vinylic halides with 1,3-dienes enabled by palladium catalysis.

Up to now, all iron-based high-T_c superconductors contain a square iron lattice. Here, Wang et al. report the observation of superconductivity in an iron honeycomb lattice accompanied with pressure-driven spin-crossover, in-plane lattice collapse and insulator-metal transition.

Although polymers have been studied for well over a century, there are few examples of covalently linked polymer crystals synthesized directly from solution. Here, the authors demonstrate a strategy to synthesize single crystalline 1D metallo-covalent organic frameworks by combining dynamic covalent chemistry and metal-ligand coordination.

The construction of three-dimensional covalent organic frameworks for gas separation is challenging due to the similar physicochemical properties of the gas mixture. Here, the authors report functional three-dimensional covalent organic frameworks by fine-tunning the pore environment with pyridine units to achieve effective separation of ethane from ethylene.

The simultaneous construction of two different types of chiralities is challenging. Here, the authors report a cationic gold-catalyzed asymmetric hydroarylation of ortho-alkynylaryl ferrocene derivatives, which enabled the simultaneous construction of axial and planar chirality.

The selective cleavage of inert C(sp3)-C(sp3) bonds and their subsequent functionalization is an important goal in synthetic organic chemistry. Here, the authors developed consecutive C–C bond cleavage from stable trisubstituted acids via photocatalysis and copper catalysis.

3D covalent organic frameworks (COF) show interesting hierarchical arrangements of nanopores and open sites but their synthesis remains challenging. Here the authors report a fluorescent AIEgen-based 3D COF and demonstrate application as a coating material for white LEDs and for sensing of picric acid

Tuning of molecular switches in solid state toward stimuli-responsive materials attracted attention in recent years but has not yet been realized in three-dimensional (3D) covalent organic frameworks (COFs). Herein, the authors demonstrate a stable and switchable 3D COF which undergoes reversible transformation through a hydroquinone/quinone redox reaction.

The emergence of universal collective behaviour is demonstrated through collisions of electron droplets containing up to five particles, which exhibit strong all-body correlations characteristic of a Coulomb liquid.

Boron neutron capture therapy (BNCT) is a type of radiotherapy that induces cell damage through a localized nuclear reaction. Here the authors describe the design of a carborane-based covalent organic framework as a boron capsule loaded with immune adjuvants for concurrent BNCT and immunotherapy, promoting anti-tumour immune responses in preclinical cancer models.

Characterization of the genetic architecture underlying the 7 pairs of contrasting traits studied by Mendel and the over 70 additional agronomic traits in pea (Pisum sativum) reveals their molecular details and provides tools for further studies in pea genetics, functional genomics and crop improvement.

Nonlinear optical crystals suitable for the UV spectral region could simplify short-wavelength generation and make it more efficient. Here, the authors design and demonstrate that one of two asymmetric borate polymorphs exhibits promising optical and mechanical properties for generating UV light.

Structure determination of covalent organic frameworks (COFs) is the key to pushing the development of COF-based materials further but precise determination of the structure of COFs is challenging. Here, the authors develop a universal ab initio structure determination method for polycrystalline 3D COFs using cryo-cRED by combining hierarchical cluster analysis with cryo-EM technique and demonstrate COF structures with atomic preciscion and up to 0.79-angstrom resolution.

Three-dimensional covalent organic frameworks hold great potential for diverse applications, but their structural diversity is constrained by the synthetic approaches available. Now it is shown that ‘eight-connected’ building blocks with reduced symmetry enable the synthesis of such frameworks with rare topologies and enhanced gas adsorption performance.

Covalent organic frameworks (COFs) have remained difficult to grow as single crystals. Now, amphiphilic amino-acid derivatives that assemble in micelles in aqueous solutions have been shown to promote the growth of a variety of imine-bridged COFs into single crystals, in a step-by-step fashion, within their hydrophobic compartment.

Zero-dimensional metal halides exhibit intriguing photophysical properties; however, developing their general design principles remains challenging. Now it has been shown that two-dimensional perovskites can be converted into zero-dimensional octahedral metal halides through solvent incorporation. The resulting materials feature near-unity photoluminescence quantum yields. Structural rigidity and the choice of metal cation are key parameters to tune the exciton recombination dynamics.

Triple-cation perovskite solar cells are more stable than formamidinium lead iodide but possess more defects. Here, grain boundary cracks and passivate interfacial defects are patched using ammonium formate which forms a stable adduct on the perovskite surface.

Here, by analyzing 306481 microbial genomes from human-associated microbiomes, the authors reveal a largely unexplored biosynthetic landscape of ribosomal peptides (RiPPs), identifying protective peptides that obstruct pathogen biofilms and regulate gut microbiota in disease models, underscoring their significant therapeutic potential.

While the reported methods for the synthesis of organoselenium compounds mainly employ preformed activated selenium reagents, the direct utilization of elemental selenium in the synthesis is a more attractive but challenging strategy. Here, the authors report the rapid synthesis of versatile organoselenium compounds via mechanical stimulation.

Plastid terminal oxidase (PTOX) is efficient in photoprotection in stress-tolerant plants. Transferring this activity to different species requires modifications to the thylakoid structure to allow PTOX access to the Photosystem II acceptor pool.

Materials with oxygen hyperstoichiometry received great attention in solid oxide fuel cells field because of the low activation energy of interstitial ion migration. Here the authors revealed the relationship between the structure and oxide ion migration for the whole series of CeNbO4+δ compounds.

Full utilization of ZSM-5 shape-selectivity is restricted by crystal external surface acid sites and co-existence of two different sized channels. Here, the authors synthesize reverse Al zoned ZSM-5 with sinusoidal channel preferentially opened to its inert external surface to achieve 99.3% p-xylene selectivity.

Little attention has been paid to the fundamental mechanism of molecular self-assembly into crystallised films or wires on surfaces. Here the authors use real time in-situ scanning probe microscopy to monitor the growth trajectories of organic semiconducting films as they crystallize from an amorphous solid state under ambient conditions.

The biogeochemical roles of the plastisphere regulating N cycling are elusive. This study reveals the plastisphere as an emerging nitrifying niche, featured by distinct shifts in nitrifiers and potential substrate exchanges compared to seawater.

Here the authors have developed a superconducting microwave frequency comb that is fully integrated, easy to manufacture, and operates with ultra-low power consumption, and could significantly advance microwave photonics and quantum processor integration.

Designing core/shell quantum dots with desired optoelectronic properties remains a challenge. Here, the authors investigate the negative and positive trions dynamics within a quantum dot, proposing an Auger engineering strategy based on geometry-dependent dielectrics for tuning optical properties.

Genomic and phenomic screens of 827 wheat landraces from the A. E. Watkins collection provide insight into the wheat population genetic background, unlocking many agronomic traits and revealing haplotypes that could potentially be used to improve modern wheat cultivars.

Caloric restriction is a common approach to weight reduction, however, weight regain is common. Here the authors report that caloric restriction reduces the abundance of Parabacteroides distasonis in the gut and alters serum bile acid (BA) profile, which contribute to weight regain in mice.

Two-dimensional MOFs can possess porosity and electrical conductivity but are difficult to grow as single crystals. Here, by balancing in-plane and out-of-plane interactions, single crystals of sizes up to 200 µm are grown, allowing in-plane transport measurements and atomic-resolution analysis.

Chinese vegetable production accounts for 1.7% of the global harvest area of crops but uses 7.8% of the chemical fertilizer and produces 6.6% of the crop-sourced greenhouse gas emissions of the global agricultural sector. An innovative management programme offers opportunities for producing more vegetables with lower environmental impacts.

The early identification of metabolic disorders could improve or prevent overt disease. Here the authors show that the circulating concentration of hyocholic acid (HCA) species is decreased in the context of obesity and diabetes and increased after gastric bypass surgery in humans, and further that serum HCA species are predictive of metabolic outcomes in healthy individuals.

Recently, the asymmetric bifunctionalization of alkenes has received much attention but the development of enantioselective alkoxyalkenylation has posed a considerable challenge and has lagged largely behind. Here, the authors report a palladium-catalyzed enantioselective alkoxyalkenylation reaction, using a range of primary, secondary, and tertiary γ-hydroxyalkenes with alkenyl halides.

The mechanisms of the partial reproductive isolation between the two subspecies of rice remains obscure. Here, the authors show that the two adjacent genes form a killer-protector system to induce hybrid male sterility and reproductive isolation between indica and japonica.

Pu-erh tea displays cholesterol-lowering properties. Here, Huang et al. show that this is mostly due to the action of a pigment in Pu-erh tea that induces changes in certain gut microbiota and bile acid levels, thus modulating the gut-liver metabolic axis.

The mechanisms of stalled fork degradation in BRCA1/2-deficient cells remain unclear. UFL1, an UFM1-specific E3 ligase, was found to catalyze PTIP UFMylation at lysine 148, promoting stalled fork degradation by the MRE11 nuclease.

The roles of marine plastisphere in global nitrogen cycling are largely unknown. Here, the authors indicate that the plastisphere could act as a potential source of N2O production, which is mainly regulated by the biotic denitrification

Little is known about the regulation of RNA interference (RNAi). Shan et al. constructed a reporter system to monitor RNAi activity and identified a small molecule that increases RNAi by facilitating the interaction between small RNAs and a protein involved in small RNA loading and processing.

With extralarge pores, zeolites could catalyse reactions between larger molecules. Here a zeolite with the largest pores to date is synthesized, about 25 ångstroms across; the structure is also chiral, which is useful in the separation of enantiomorphic molecules. The synthesis is done by crystallization of a gel of germanate and silicate dissolved in a bulky organic molecular template, using high-throughput techniques.