Using an X-ray laser, the method revealed atomic motions in a simple catalyst, opening the door to study more complex molecules key to chemical processes in industry and nature.
Researchers design a nanovaccine that detects MRSA toxins, kills bacteria with heat, and captures antigens to train the immune system for lasting protection.
Researchers identify hierarchical moire patterns in 2D materials, enabling a tunable platform for designing next-generation quantum materials at the atomic scale.
New study reveals how dynamic nanodomains in lead halide perovskites impact charge transport, offering a path to more efficient and stable solar cells.
New method simulates electronic friction effects on quantum motion, explaining hydrogen diffusion on copper with relevance to catalysis and energy storage.
Phycicists have used cutting-edge nanolithography to create what they believe may be 'the world's smallest violin', which is small enough to fit within the width of a human hair.
A protein that gives fleas their bounce has been used to boot out bacteria cells, with lab results demonstrating the material's potential for preventing medical implant infection.
For the first time, the newly developed method of terahertz calorimetry makes it possible to experimentally examine the role of water in complex biological processes.
Scientists have conducted a theoretical analysis demonstrating how a 'topological quantum battery' - an innovative device that leverages the topological properties of photonic waveguides and quantum effects of two-level atoms - could be efficiently designed.
Researchers develop an energy-efficient device with near-human color discrimination capabilities, demonstrating great potential for computer vision applications.
