Using DNA origami, scientists have built innovative nanostructures that pave the way for advanced robotics that can deliver targeted drugs - plus a tiny map of Australia and mini dinosaurs.
This new platform offers significant advancements in super-resolution microscopy, enabling fast and precise 3D imaging of multiple cellular structures while the extracellular environment can be controlled and flexibly adjusted.
Scientists demonstrate how atomic size differences control metal catalyst structure at nanoscale, achieving major improvements in fuel cell efficiency and chemical processes.
Researchers developed a method to functionalize graphene using a 1-nm dielectric carbon layer, enabling capture molecules to alter signals without disrupting graphene's properties.
Researchers use traditional flat-knitting techniques to fabricate flexible, lightweight metasurfaces--large-aperture antennas--that can easily be stowed and deployed for long-range communications.
