Inner Workings of Atomically Thin Transistors
Scientists reveal conductive edges and thread-like flaws using a specialized imaging technique of interest for next-generation electronics.
Scientists reveal conductive edges and thread-like flaws using a specialized imaging technique of interest for next-generation electronics.
Visible lasers offer exquisite control of x-ray light in a tabletop apparatus, potentially providing access to new insights to chemical reactions, proteins, and even atoms’ inner workings.
Scientists discover another design principle for building nanostructures.
Scientists show how a buckyball buffer helps conduct electricity in only one direction, vital for molecule-sized circuits.
Understanding differences in modeling soil water will help scientists simulate how this moisture affects the climate.
First atomically thin, halide perovskite sheets could be an alternative to graphene for future electronics.
Novel self-assembly can tune the electronic properties of graphene, possibly opening doors for tiny, powerful electronic devices.
Implanted helium ions “tuned” complex behaviors—enabling design of new materials for efficient electricity storage and testing theories.
Meticulously designed oxide thin films exhibit well-defined ON/OFF states that could be used in small, energy-efficient electronics.
Superacid treatment of semiconductors could lead to atomically perfect transparent displays and energy-efficient computer chips.
First-of-their-kind images could aid in use of DNA to build tiny, lightweight devices.
International team shows that modified graphene is 105 times more sensitive at detecting ammonia.