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Cyanide-bridged CoFe coordination networks exhibit photomagnetism because of coupled charge-transfer and spin transition. Now, femtosecond X-ray and optical absorption spectroscopies have enabled the electronic and structural dynamics of this light-induced process to be disentangled and show that it is the spin transition on the cobalt atom, occurring within ~50 fs, that induces the Fe-to-Co charge-transfer within ~200 fs.
Moving towards renewable energy sources requires pathways for efficiently converting electricity to chemicals, and gas-fed CO2 electrolysers show promise. Now, the layer-by-layer assembly of a weak-acid cation exchange layer has been shown to affect the local pH in a bipolar-membrane-based gas-fed CO2 electrolyser, improving the conversion efficiency of CO2 to CO by suppressing the competing hydrogen evolution reaction.
Electronic–vibrational interplay can enable electron and energy transfer processes to be regulated. Now, coherence spectroscopy has been used to disentangle two vibrational pathways that control an electron transfer reaction. It has been shown that a fast, effectively ballistic, electron transfer along one vibrational path acts like a pulse to generate a coherent wavepacket along another vibrational pathway.
The role of the biexcitonic triplet-pair state 1(TT) during triplet–triplet annihilation events in singlet-fission materials has been the subject of recent debate. Now, emissive 1(TT) states have been shown to be direct products of triplet–triplet annihilation in both endothermic and exothermic singlet-fission materials.
A method for the covalent labelling of proteins by installing a biostable peptide nucleic acid (PNA) tag has now been developed. The PNA label serves as a generic landing platform that enables the recruitment of fluorescent dyes via nucleic acid hybridization and fluorophore removal by toehold-mediated strand displacement. Imaging of cell surface receptors, including internalized receptors, has been demonstrated using this approach.
Diatomic C2 is an elusive species that has only been indirectly observed in the gas phase. It had previously been stabilized in the condensed phase using two ligands, but now a monoligated L→C2 complex has been prepared with a bulky phosphine ligand (L) bearing two imidazolidin-2-iminato groups. Reactivity studies and theoretical quantum chemical analysis point to the C2 moiety having a dicarbene character.
Low-temperature scattering leads to the formation of quantum resonances or quasi-bound states, which are observable as peaks in the measured collision cross-sections. Now it has been shown that two different formation mechanisms, quantum tunnelling and quantum reflection, can be distinguished by measuring and comparing elastic and inelastic scattering, which probe the spatial localization of the resonance wavefunctions.
Mirror-symmetry breaking in chiral systems by a chiral solvent has remained poorly understood for decades. Now, the supramolecular polymerization of triphenylene derivatives has shown that—through the additive effects of polymerization—the cumulative entropic effects of the interactions between chiral solvents and solutes create measurable differences in free enthalpy.
Bacteria use thioester-bond-containing proteins to covalently bind to host surfaces and withstand large mechanical shocks. Now, thioester bond reactivity has been shown to be force-dependent: forces >35 pN inhibit bond cleavage by primary amine ligands, whereas forces <6 pN enable reversible reformation. This force-modulated thioester bond reactivity could potentially enable bacterial mobility and a route by which they optimize infection.
Metal–organic frameworks (MOFs) can combine porosity and magnetic order within their lattice, which makes them attractive for the development of stimuli-responsive magnets. Now, a MOF has been prepared that converts from a ferrimagnet to a paramagnet with CO2 uptake, and returns to the ferrimagnetic state on releasing CO2.
As a consequence of their high instability, main-group carbonyl complexes are rare — only a few have been detected, typically in low-temperature matrices. Now, two silicon–carbonyl complexes have been isolated using innovative substituent patterns at the Si centre; their reactivity resembles that of their transition-metal counterparts.
Artificial photosynthesis represents a promising method of generating hydrogen for our clean and sustainable energy needs. Now, photocatalytic nanofibres have been developed that incorporate photosensitizers and catalysts into well-defined self-assembled structures for efficient hydrogen production.
Artificial systems capable of photocatalytic hydrogen production are not typically based on precisely controlled scaffolds. Now, statistical seeded crystallization of block copolymers—bearing either a pendant cobalt catalyst or a photosensitizer—from solution has been shown to yield recyclable, colloidally stable nanofibres that can be tailored to promote photocatalytic hydrogen production from water.
The self-assembly of haemoglobin-containing erythrocyte membrane fragments onto the surface of preformed coacervates has been used to make hybrid synthetic cells that can initiate nitric-oxide-induced vasodilation. These synthetic cells encapsulate enzymes that generate a flux of nitric oxide, as well as exhibiting high haemocompatibility and increased blood circulation times.
The majority of discrete structures obtained by self-assembly possess high symmetry, and thus low complexity: all subunits relate to their neighbours in a similar manner. Now, the spontaneous formation of complex low-symmetry assemblies produced from a single building block has been demonstrated using a systems chemistry approach. The single building block oligomerizes to form specific homomeric cyclic macromolecules that adopt a folded conformation.
Metabolic labelling with unnatural sugars can be used to selectively label tumours with chemical tags. These tags then enable the targeted delivery of molecular cargo including diagnostic and therapeutic agents. This Review Article discusses progress in the design and delivery of unnatural sugars for metabolic labelling of tumour cells and the subsequent development of tumour-targeted chemistry.