Researchers have achieved orbital hybridization in graphene-based quantum dots for the first time. This breakthrough provides ...

Quantum dots are tiny, man-made structures often called “artificial atoms” because they can trap and control electrons in ...

Researchers demonstrate orbital hybridization in graphene-based quantum dots, revealing how anisotropic confinement ...

A research team led by Professor Sun Qing-Feng in collaboration with Professor He Lin's research group from Beijing Normal ...

A research team led by Professor Sun Qing-Feng in colloboration with Professor He Lin's research group from Beijing Normal University has achieved ...

A research team led by Professor Sun Qing-Feng in colloboration with Professor He Lin’s research group from Beijing Normal University has achieved orbital hybridization in graphene-based artificial ...

Iridium-doped iron-cobalt (Fe-Co-Ir) alloys, previously identified through machine learning, have been shown to have enhanced magnetic properties, surpassing even the widely used pure Fe-Co alloy.

On Monday, he visited Los Alamos National Laboratory, home to the top secret project during World War II that created the atomic bomb. A fossil fuel executive and graduate of MIT, Wright ...

Through high-throughput screening, they identified an efficient duplex metal atomic electrode interface ... derived s and p peaks to high-energy orbitals. Dynamic evolution of adaptive matching ...

That, of course, is a reference to the World War II top secret development of the atomic bombs that were dropped on Hiroshima and Nagasaki in early August 1945, ending the Pacific War with Japan ...

Electron orbitals within the layers are represented as sitting atop ... In the unmagnetized state, the excitons aren’t trapped but extend over multiple atomic layers, making them three-dimensional.