Researchers investigated the fatigue behavior of 2D hybrid materials, opening doors to their widespread use in real-world applications. Researchers investigated the fatigue behavior of 2D hybrid ...

Two-dimensional materials are only a few atoms thick yet hold great promise for the electronics of tomorrow. Because they are so thin, they can be piled in strange, twisted configurations that yield ...

Finding new materials with useful properties is a primary goal for materials scientists, and it's central to improving technology. One exciting area of current research is 2D materials—super-thin ...

The mechanical strength and toughness of engineering materials are often mutually exclusive, posing challenges for material design and selection. To address this, a research team from The Hong Kong ...

Molecular 2D materials find immense applications in materials science, owing to their wide structural variety and easy controllability. Establishing a simple and efficient method for their synthesis ...

Robotic stacking of 2D material layers on a heated substrate while applying pressure pushes out residues such as polymers from between the layers, resulting in atomically clean interfaces between ...

Nanoelectronics deal with extremely small electronic components — transistors, sensors and circuits that can fit on the tip of a needle. This technology powers our everyday lives through devices such ...

2D-XRD, or two-dimensional X-ray diffraction, is a powerful analytical technique used to study the atomic and molecular structure of crystalline materials at the nanoscale. It provides detailed ...

The unique properties of two-dimensional (2D) materials, which are only a few atoms to a single atom thick, differ from those of their three-dimensional (3D) counterparts. 2D materials have had a ...