Get Instant Summarized Text (Gist) Graphene quantum dots have successfully demonstrated orbital hybridization, a process previously unachieved in artificial atoms. By altering the potential from ...

Their findings, entitled “Orbital hybridization in graphene-based artificial atoms” was published in Nature (DOI: 10.1038/s41586-025-08620-z). This work marks a significant milestone in the ...

Researchers demonstrate orbital hybridization in graphene-based quantum dots, revealing how anisotropic confinement influences electronic states at the atomic scale. Quantum dots, often described as ...

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 ...

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 ...

Henan Institute of Advanced Technology, Zhengzhou University, Zhengzhou 450003, China ...

However, they had not yet been able to simulate orbital hybridization—a fundamental process in real atoms where different types of electron orbitals (like s and d orbitals) combine to form new ...

The group's focus is on the revolutionary design, proven manufacturing processes and rigorous testing to deliver superiority in UAV propulsion systems and flight critical components.

"We were amazed to find such a clear imprint of the different orbital parameters on the climate record," added lead author Stephen Barker, a professor at Cardiff University, in the UK. "It is ...

Orbital hybridization in artificial atoms is achieved by altering their shape, and the anisotropy of the confining potential gives rise to the hybridization between quasibound states with ...