New Technique Shows Protein Changes in Intact Microbial Communities
Mass spectrometry and high-performance computing combined, allowing scientists to study proteins that link internal processes to community attributes.
Mass spectrometry and high-performance computing combined, allowing scientists to study proteins that link internal processes to community attributes.
First atomically thin, halide perovskite sheets could be an alternative to graphene for future electronics.
Microporous polymer separator prevents specific molecules from crossing battery and causing degradation and shorter lifetimes.
Novel self-assembly can tune the electronic properties of graphene, possibly opening doors for tiny, powerful electronic devices.
Scientists transformed flexible one-dimensional molecular chains into a structured, well-defined porous three-dimensional material.
Predicting nanosystems with unanticipated properties can advance next-generation solar panels and 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.
Researchers trapped and detected ensembles of electrons, an important step in isolating single electrons for use in a new generation of low-power supercomputing.
Disentanglement reveals exotic magnetic properties in a ytterbium-based compound.
Community composition is vital to managing native grasslands amid climate and precipitation variations.