By twisting layers of graphene, researchers discovered a unique electronic crystal where electrons freeze in place yet allow ...

Graphene is a material poised to revolutionise the electronics and semiconductor industries. Once a laboratory curiosity, it now faces the critical challenge ...

Graphene is an atomic-scale honeycomb lattice made of carbon atoms. Graphene is undoubtedly emerging as one of the most promising nanomaterial because of its unique combination of superb properties, ...

This approach allowed the researchers to precisely control the shape and structure of the graphene nanoribbons at the atomic level. The 'Z-shape' design allows for the asymmetric fabrication by ...

The breakthrough came from Ruiheng Su, an undergraduate student at UBC, who observed a unique configuration in twisted ...

“Several theory groups have speculated that analogues of these structures could emerge in quantized anomalous Hall systems, ...

Electron transport in bilayer graphene exhibits a pronounced dependence ... on the "valley," a quantum state in an electron's energy structure that functions as a discrete data storage unit ...

This approach allowed the researchers to precisely control the shape and structure of the graphene nanoribbons at the atomic level. The Z-shape design allows for the asymmetric fabrication by ...

The unexpected result started a debate in the community because theory predicted that it would take billions of years for a proton to permeate through graphene’s dense crystalline structure ...

The results were incredibly promising. "The homogeneous fibrous structure of graphene embedded with nanodiamond showed significant stability in harsh plasma environments," Sankaran says.