![Crystal structure of the parent compound of a calcium-strontium-based cuprate superconductor [(Ca/Sr)2CuO3]](/-/media/bes/images/highlights/2015/02/figure-1-large.jpg?h=640&w=482&la=en&hash=D1DB4EF52CFDD381CF2E3555D27C4B6F5EB9C292E8C55E49392F2B5AA679B0B5 "figure-1-large.jpg")
New theoretical techniques predict experimental observations in superconducting materials.
Researchers have created a porous, layered material that can serve as a graphene analog, and which may be a tool for storing energy and investigating the physics of unusual materials.
New material with a layered, atomic sandwich structure has unique optoelectronic properties.
Combining computer simulations with laboratory measurements provides insights on molecular-level flexibility.
Experiments using novel magnetic nanostructures confirm theoretically predicted behavior – bolstering their utility as a tool for understanding complex magnetic materials.
New metal oxide material works at temperatures low enough to improve fuel cell efficiency.
Lithium-ion batteries could benefit from this inexpensive method.
New microscopy technique reveals giant enhancement of coupling between magnetic and electric dipoles that could lead to novel electronic devices.
Coexistence of two states of matter that normally avoid one another is revealed by inelastic neutron scattering experiments.
Atomic-scale details of electron distribution reveal a novel mechanism for current to flow without energy loss.
Discovery demonstrates how metamaterials may be used in non-invasive material imaging and sensing, and terahertz information technologies.
Stroboscopic x-ray pulses scatter from a vibrating crystal and reveal how energy moves.
