Degradable pacemakers and artificial neurons showcase how flexible, tissue-compatible electronics are revolutionising medicine. But translating these materials from lab bench to clinic requires solvin ...

Motionless atoms can trap liquid metal in a strange new state that shouldn’t exist. Scientists have discovered that a liquid does not always behave the way it seems. Even when a material is fully ...

A burst of invisible light can do more than illuminate a surface. In a new study, Michigan State University researchers used ...

There, stretching across the heart of the cloud of cosmic dust and gas, lies a giant, oddly linear, bar-shaped cloud of ...

Louis E. Brus, a chemist and Nobel laureate who discovered quantum dots, tiny crystals that emit various colors of light ...

Researchers announced that they have achieved the world's first elucidation of how hydrogen produces free electrons through ...

Researchers at Kyushu University have shown that careful engineering of materials interfaces can unlock new applications for ...

Placing a thin layer of molybdenum disulfide on diamond enables current flow at room temperature, opening a new pathway for diamond-based electronic devices.

Associate Professor Yuichiro Matsushita of Materials and Structures Laboratory, Institute of Science Tokyo, Mitsubishi ...

The 2D devices fabricated using CDimension’s ultra-thin films have demonstrated up to a 1,000X improvement in ...

How atomic-layer deposition and hybrid dielectrics are redefining reliability and scaling for AI-era semiconductors.

UCLA researchers identify a metal with ~3× the heat conduction of copper, offering a potential leap in cooling for chips, AI accelerators, and next-gen electronic systems.