A new method in electron microscopy enables sub-20-picometer targeting of individual atoms without prior exposure, opening the door to atom-specific analysis and control.
Researchers discovered a new ion transport mechanism in nanofiltration membranes, offering key insights for improving lithium recovery from magnesium-rich brines.
By tracking the movement of RNA molecules inside the nucleolus using advanced imaging and genomics techniques, the new method allows researchers to watch these processes as they unfold without destroying the cell or its fragile components.
Scientists compare current theories to explain the behaviour of heat flow in nanoscale materials, extremely important for the improvement of electronic devices.
Researchers developed a sponge-like material with long, microscopic air pockets that uses sunlight and a simple plastic cover to turn saltwater into freshwater.
Scientists mapped the bacterial flagellum in atomic detail, revealing it as a target to disarm infections without killing bacteria or driving antibiotic resistance.
Breaking inversion symmetry in materials allows deviations from Ohm's law, enabling nonlinear effects that could drive future nano- and quantum-electronic devices.
Researchers developed tunable photonic crystal biosensors using magneto-plasmonic nanoassemblies to enhance fluorescence for ultrasensitive disease biomarker detection.
