Science has solved a century‑old mystery, finally explaining how electrons can literally pass through barriers that should otherwise block them.

When placed under a powerful laser field (i.e., under strong-field ionization), electrons can temporarily cross the so-called quantum tunneling barrier, an energy barrier that they would typically be ...

A research team led by Pasquale Scarlino at EPFL has built a small, tunable detector capable of sensing individual microwave ...

Recently, Professor Dong Eon Kim from POSTECH's Department of Physics and Max Planck Korea-POSTECH Initiative and his research team have succeeded in unraveling for the first time the mystery of the ...

Researchers have built an upgraded quantum microscope that can map momentum-resolved tunneling spectra in graphene at room ...

Scientists achieve optical measurements at atomic scales using quantum electron tunneling, surpassing conventional microscopy limits by nearly 100,000 times with standard lasers. (Nanowerk News) From ...

Light-induced ultrafast electron dynamics significantly impacts the fundamental processes in nature, such as molecular bond breaking and formation, chemical reactions, and biological metabolism.

Scientists developed a new device capable of directly observing hidden electron interactions in graphene at room temperature.