Researchers have developed a rapid computing method to predict properties of hundreds of materials for quantum applications, followed by precise fabrication and evaluation of top candidates.
Scientists have achieved a series of milestones in growing a high-quality thin film conductor, suggesting in a new study that the material is a promising candidate platform for future wearable electronics and other miniature applications.
Scientists develop flexible, lead-free perovskite membranes for X-ray detection, achieving high sensitivity and stability. This advance could enable wearable radiation dosimeters.
Physicists are using an ultrafast microscope to reveal how electrons move in a new type of solar cell material. The results provide insights into how the material can be used even more efficiently for photovoltaics.
Researchers have advanced medical nanotechnology by creating neutrophil-engineered nanovesicles rich in bactericidal proteins, enhancing the immune response for treating infectious wounds.
Researchers developed advanced microfluidic sensor arrays that use fluorescent probes to simultaneously visualize and quantitatively detect multiple heavy metal ions in environmental water in real-time.
Organic molecules influence gold nanoparticle redox potential by up to 71 mV. The study, using experiments and simulations, reveals capping agents' role and kinetic effects, aiding in nanoparticle customization for catalysis, electronics, and drug delivery.
Scientists looking to measure the dynamics of how materials change have developed a new technique that leverages X-ray photon correlation spectroscopy (XPCS), artificial intelligence and machine learning.
