A research team from Skoltech, Ben-Gurion University of the Negev, N.M. Emanuel Institute of Biochemical Physics RAS, and ...

A study conducted by researchers from the Changchun Institute of Optics, Fine Mechanics and Physics (CIOMP) of the Chinese ...

Defects in spintronic materials, once seen as limitations, may now be key to progress. Chinese researchers discovered that ...

To address these issues, defect engineering that focuses on increasing the number of structural defects in the material and thus increasing the surface area throughout the whole volume has been ...

AI-enhanced defect engineering strategies, such as entropy and dislocation engineering, composition optimization, grain boundary design, and inverse design techniques, were examined for producing TE ...

Specifically, defect engineering can help to adjust the local atomic structure and coordination environment of the battery electrode material, regulate the electronic and structural ...

Defect engineering, one of the important electrocatalyst modification strategies, has gradually attracted extensive attention of researchers in the field of electrocatalysis.

Scientists have turned a longstanding challenge in electronics-material defects-into a quantum-enhanced solution, paving the ...

New microscopy techniques now enable direct imaging of atomic defects' electric field polarization, unlocking understanding of defect tuning mechanisms for enhanced electrocatalysis and beyond.

Atomic-scale defects in crystals can make excellent quantum memories that can be written and read out using lasers, and could form the basis of future quantum communications and computing systems.