Combining ultra-thin molybdenum disulfide with flexible strontium titanate nanomembranes creates advanced materials that can be used in a variety of low-power, high-performance electronic and sensing devices.
Using a specially developed etching apparatus, researchers produced mesoporous silicon layers with countless tiny pores and investigated their electrical and thermal conductivity.
Researchers develop hydrogel microspheres with data-encoding bacteria that enable room-temperature DNA storage with fluorescence-based retrieval, combining advantages of both in vivo and in vitro methods.
Using an approach called DNA origami, scientists have developed a technique that could lead to cheaper, reusable biomarker sensors for quickly detecting proteins in bodily fluids, eliminating the need to send samples out to lab centers for testing.
Researchers enhanced Stimulated Emission Depletion (STED) microscopy by replacing traditional fluorophores with nanographenes, enabling the observation of longer-duration processes, overcoming a limitation of STED microscopy to date.
Researchers gain critical insights into atomic-scale synthesis of cadmium selenide nanoplatelets, enabling systematic production of these atom-thin materials with extraordinary optical properties.
