Researchers developed an ultra-thin, flexible film that could power next-generation wearable devices using body heat, eliminating the need for batteries. This technology could also be used to cool electronic chips, helping smartphones and computers run more efficiently.
This demonstration underscores the potential of engineered monolayer graphene LWIR detectors operating at room temperature, offering high sensitivity as well as dynamic spectral tunability for spectroscopic imaging.
Scientists used an entirely innovative process to change metal-organic frameworks (MOFs) by grafting hydrocarbon chains. The resulting superhydrophobic properties are interesting for use as self-cleaning surfaces.
Scientists used frequency-modulated atomic force microscopy to reveal the submolecular structure of microtubule (MT) inner surface and visualize structural defects in the MT lattice, providing valuable insights into the complex dynamic processes that regulate microtubule function.
Using perovskite crystals and 3D printing, researchers developed customizable radiation detectors with fast response times and greater durability, opening new possibilities for medical and research applications.
This research presents a unified theoretical scheme that sheds light on the complex relationship between the symmetries of these microstructures and the generation of optical singularities, opening new avenues for advancements in photonics and optics.
Researchers have developed nanofluidic devices capable of manipulating single nanoscale objects, including DNA, nanoparticles, proteins, and small molecules in solution. They introduced 'nanofluidic manipulation', enabling precise nanoscale control.
A new class of magnetism called altermagnetism has been imaged for the first time in a new study. The findings could lead to the development of new magnetic memory devices with the potential to increase operation speeds of up to a thousand times.
