Graphene quantum dots mimic orbital hybridization
A research team led by Professor Sun Qing-Feng in collaboration with Professor He Lin's research group from Beijing Normal ...
Technology Networks1d
Researchers Achieve Breakthrough in Graphene-Based Artificial Atoms
Researchers have achieved orbital hybridization in graphene-based quantum dots for the first time. This breakthrough provides ...
Nanowerk4d
Orbital hybridization achieved in graphene quantum dots for the first time
Researchers demonstrate orbital hybridization in graphene-based quantum dots, revealing how anisotropic confinement ...
EurekAlert!4d
Quantum leap: Graphene unlocks orbital hybridization
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 ...
Nanowerk6h
Quantum tornadoes observed among electrons
Quantum tornado in momentum space: Electrons form vortices in the quantum material tantalum arsenide (TaAs). Momentum space ...
Mirage News4d
Graphene Breakthrough: Quantum Leap in Hybridization
A research team led by Professor Sun Qing-Feng in colloboration with Professor He Lin's research group from Beijing Normal University has achieved ...
Earth.com6d
Swirling electrons could power future technology
Scientists observed electron swirls in tantalum arsenide, revealing quantum vortex structures in momentum space.
Knowridge Science Report2d
Scientists unlock real atomic behavior in lab-made quantum dots
Quantum dots are tiny, man-made structures often called “artificial atoms” because they can trap and control electrons in ...