This study is led by Prof. Shuangyin Wang (College of Chemistry and Chemical Engineering, Hunan University) and Prof. Chen Chen (College of Chemistry and Chemical Engineering, Hunan University).

Scientists can now create and control tiny internal defects in ultra-thin materials, enabling new properties and potential breakthroughs in nanotechnology. (Nanowerk News) Materials scientists at the ...

Relying solely on end-of-line testing isn't enough when security, traceability, and mission reliability are vital.

Layered double hydroxides (LDHs) are emerging as promising electrocatalysts for the oxygen evolution reaction (OER), a key barrier in clean hydrogen ...

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.

• The underlying migration mechanism of Mg 2+ in cathode materials and roles of defects in Mg 2+ migration in cathode materials were studied. • Applications of defect engineering to Mg 2+ migration in ...

A recent review article published in Advanced Materials explored the potential of artificial intelligence (AI) and machine learning (ML) in transforming thermoelectric (TE) materials design. The ...

Chipmakers are plotting out a strategy to scale the transistor to 10nm and beyond. Migrating to these nodes presents a number of challenges, but one issue is starting to gain more attention in the ...

Defect states refer to electronic energy levels that arise from imperfections or irregularities in the crystal structure of materials, particularly in semiconductors and insulators. These ...