
Oxide Interfaces Put New Twist on Electron Spins
Interfaces made by stacking certain complex oxide materials can tune the quantum interactions between electrons, yielding exotic spin textures.
Interfaces made by stacking certain complex oxide materials can tune the quantum interactions between electrons, yielding exotic spin textures.
Patterned arrays of nanomagnets produce X-ray beams with a switchable rotating wavefront twist.
Using two methods is better than one when it comes to observing how solar cells form and improving cell properties.
Studies of a common catalyst suggest strategies for improving the conversion of a natural gas component to useful chemicals.
Understanding platinum degradation could reduce waste and lower cost of a promising green technology, hydrogen fuel cells.
Researchers find that fungal spores are most abundant during initial growth, while bacteria predominate during flowering and fruit development.
Monitoring photo-excited electrons in real time with nanometer sensitivity reveals strengths and weaknesses in a common light-harvesting material.
Ozone injection may lead to cleaner, more efficient internal combustion engines.
Using cold temperatures and machine learning, researchers visualized individual molecules in a synthetic soft material for the first time.
Designer polymers effectively mimic natural proteins in proton transport across membranes for health and energy technologies.
Insight into charge generation induced by light could enable the design of better photocatalysts made from nanomaterials.
Scientists reveal oxygen’s hidden talent for filling atomic gaps in 2D semiconductors and the surprising role of electron spin in electronic conductivity