Thank you for visiting nature.com. You are using a browser version with limited support for CSS. To obtain
the best experience, we recommend you use a more up to date browser (or turn off compatibility mode in
Internet Explorer). In the meantime, to ensure continued support, we are displaying the site without styles
and JavaScript.
Clathrin, a three-legged protein complex, can form regular two-dimensional lattices on a variety of substrates. These lattices can be functionalized with nanoparticles or enzymes for sensing applications.
Thin-film transistors made from solution-processed single-walled carbon nanotubes are used to fabricate large-scale integrated arrays of complementary static random access memory cells.
Silicon pillars with elliptical cross-section are used to fabricate efficient metasurfaces that allow simultaneous control of the phase and polarization of the transmitted electromagnetic radiation.
The scanning tunnelling microscope can be used to image and manipulate individual defects in bulk insulating hexagonal boron nitride by capping the material with a monolayer of graphene.
The generation of strain in SnTe thin films due to lattice mismatch with the PbSe substrate can be used to tune the position of Dirac nodes in momentum space.
Atomically thin gratings, fabricated in single-layer graphene, can act as nanomechanical diffraction elements for high-contrast quantum interference of phthalocyanine molecules.
Capacitively coupled quantum dots can be used to realize a thermoelectric device that decouples the direction of flow of the electrical current from that of the heat current.
Gas transport through discrete ångström-sized pores in monolayer graphene can be controlled using gold clusters formed on the surface of the graphene, which can migrate and partially block a pore.
High-frequency impedance spectroscopy using CMOS nanocapacitor arrays allows microparticles and living cells to be imaged in real time under physiological salt conditions.
Different adjacent molecules adsorbed on a surface can be distinguished by their Raman modes using a plasmon-enhanced Raman scattering technique with a spatial resolution below 1 nm.
The direction of a single photon emitted from a quantum emitter, and its coupling to a photon waveguide, can be controlled by the helicity of the optical transition.
A design approach for engineering wireframe DNA nanostructures, in which each vertex and line segment can be individually controlled, can be used to fabricate complex structures including quasicrystalline two-dimensional patterns and reconfigurable three-dimensional Archimedean solids.
Enhanced electron–phonon interactions in mono- and few-layer NbSe2 result in a significantly increased transition temperature of charge density waves compared with values in the bulk.
The incorporation of carbon nanotubes in a silica matrix produces oxygen dopant states that can emit single photons at room temperature and at wavelengths relevant for applications in telecommunications.
DNA nanotube scaffolds allow artificial myosin filaments to be engineered that can be used to probe the mechanical coordination of myosin motor ensembles.
Molecular dynamics simulations of water molecules inside carbon nanotubes show a strong coupling between the flow of water and the phonon modes of nanotubes that enhance diffusion.