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Chemistry is a branch of science that involves the study of the composition, structure and properties of matter. Often known as the central science, it is a creative discipline chiefly concerned with atomic and molecular structure and its change, for instance through chemical reactions.
A diazapentadienyl radical featuring a disubstituted carbon centre is discovered allowing the isolation and structural characterization of a stable secondary carbon radical.
Developing skeletal editing tools, especially to realize the single-atom transmutation in a ring system without altering the ring size is challenging. Here, the authors introduce a skeletal editing strategy that enables polycyclic arenols to be readily converted into N-heteroarenes through carbon–nitrogen transmutation.
The efficient encapsulation of guests by coordination cages in the solid state is prevented by their flexibility, dynamicity, and metal-ligand bond reversibility. Here, the authors report coordination cages integrated into poly(ionic liquid)s to control swelling and mechanical properties of the gels and develop efficient and regenerable supramolecular separation materials.
Molecular isomerization in solution is dependent on coupling of solute and solvent via memory-dependent friction. Here, by applying memory kernel extraction to molecular dynamics simulations, the authors demonstrate the role of friction in determining isomerization kinetics.
Dry reforming of methane is an attractive route to convert greenhouse gases into valuable syngas. Here, the authors demonstrate design strategy to prepare efficient catalysts towards activation of both C–H and C = O bonds and provide atomic-level insights into interfacial synergistic catalysis.
Ammonia production from dinitrogen is challenging due to the harsh reaction conditions required and significant energy consumption. Here, this Review discusses how plasmonic materials can offer an energetically and ecologically desirable solution to dinitrogen reduction.
A synthesis method for large-scale conjugated polymers as well as studies under operational conditions show that research on organic mixed ionic–electronic conductors continues to progress.
A diazapentadienyl radical featuring a disubstituted carbon centre is discovered allowing the isolation and structural characterization of a stable secondary carbon radical.
Transitioning to more sustainable chemicals will require the challenging replacement of fossil resources with renewable carbon and energy sources in their production. Now, integrating industrial sectors offers an interim solution to mitigate emissions in the chemical industry until technologies for closing the carbon loop can be deployed at scale.