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Studying three Weyl semimetals of the same family — TaAs, TaP and NbP — reveals how the properties of Weyl points and Fermi arcs depend on the spin–orbit coupling and on surface conditions.
This Review discusses the properties and applications of supramolecular biomaterials for drug delivery, tissue engineering, regenerative medicine and immunology.
Conducting complex oxides with correlated electrons at room temperature offer a less explored materials platform for the high conductivity and optical transparency needed for ultrathin invisible circuitry.
Thin and continuous films of porous metal–organic frameworks can now be conformally deposited on various substrates using a vapour-phase synthesis approach that departs from conventional solution-based routes.
Large single-crystalline graphene monolayers have been synthesized on a Cu–Ni alloy using a local precursor feeding method with an enhanced growth rate. The fast production of wafer-scale single crystals brings graphene closer to real applications.
An implantable, flexible mesh with embedded electrodes for sensing neural activity in vivo improves brain-sampling efficiency and reduces the amount of cortical tissue injured.
The propagation of plasmons in graphene–hexagonal boron nitride moiré patterns is experimentally studied for the first time via infrared scattering near-field optical spectroscopy.
This Review discusses the physics of electrical contacts to 2D semiconductors and the strategies adopted to improve charge injection in these materials. The requirements for efficient spin injection in spintronic devices are also presented.