糖心视频

A research team in Kiel has demonstrated a previously unknown effect in graphene鈥攁 single layer of carbon atoms whose discovery earned the 2010 Nobel Prize. For years, graphene has been seen as a promising material for nanoelectronics, thanks to its exceptional conductivity, flexibility, and stability. Now, researchers from the Institute of Theoretical 糖心视频ics and Astrophysics at Kiel University have taken this promise a step further.

In a study in 糖心视频ical Review Research, Dr. Jan-Philip Joost and Professor Michael Bonitz show for the first time that light pulses can generate electrons at specific designated locations in the material. To investigate how electrons move and interact, they simulated the effects of laser pulses on small graphene clusters. Their results open up entirely new approaches for nanoelectronics.

Light pulses as nanoscale switches

In these systems, ultrashort laser pulses act like light switches on the nanoscale. Within just femtoseconds鈥攁 millionth of a billionth of a second鈥攖hey switch electrons on and off at precisely defined spots. When a pulse strikes a graphene cluster, electrons gather at one edge. A second pulse can generate electrons almost instantly at a different site. The researchers can steer the electrons with high precision, like a traffic signal guiding them where to go.

"We discovered this spatial selectivity in a chemically completely homogeneous material鈥攇raphene consists solely of carbon," explains Bonitz. "Until now, such an effect was only known in molecules composed of different atoms with distinct absorption properties. In our graphene clusters, control emerges solely from the electronic structure and from special topological states. Even under small perturbations, the electron positions remain stable, making the control reliable."

Challenges for integration into real devices

The findings could mark a major step forward for next-generation electronics. Today's transistors operate in the gigahertz range. Graphene-based components switched by laser pulses could function in the petahertz range鈥攗p to 10,000 times faster.

In communication systems, precisely guided electron pathways could enable rapid data transfer with minimal energy consumption. This opens up possibilities for high-performance computing, AI chips, and other ultra-fast electronic systems. The challenge now is to integrate the excited electrons reliably into actual circuits.

"If these processes can be transferred into real devices, it would be a huge leap for nanoelectronics," says Joost.