Researchers Demonstrate Ultrafast Conversion of Light into Electricity

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KIEL, Germany, Dec. 21, 2018 — A team from Kiel University (CAU) filmed the conversion of light energy into a solid — an exchange that takes place in a matter of femtoseconds (fs) — using an ultrafast camera system developed by the researchers. The team was able to observe the energy exchange of the electrons with their environment in real time and distinguish individual phases.

Filming motion of electrons using ultrafast camera, Kiel University.
With the ultrafast system in the Physics Centre at Kiel University (Germany), the behavior of electrons can be filmed live. Courtesy of Jürgen Haacks, CAU.

The researchers irradiated a graphite sample with a short, intense light pulse of only 7 fs duration. The different stages in the formation of a Fermi-Dirac distributed electron gas in the graphite, after absorption of the fs laser pulse, were filmed. Graphite is characterized by a simple electronic structure, which allows its fundamental processes to be clearly observed.

The researchers found that the light particles impacting the graphite disturbed the thermal equilibrium of the electrons. Equilibrium describes a condition in which a precisely definable temperature prevails among the electrons. The research team filmed the behavior of the electrons, until equilibrium was restored after about 50 fs.

Filming the motion of electrons using an ultrafast camera, Kiel University.

Film recordings show for the first time how the energy distribution in a graphite sample changes in the ultrashort period of 50 femtoseconds. Courtesy of
Physical Review Letters.

By filming the motion of the electrons, the researchers were able to observe numerous interactive processes of excited electrons with the impacting photons, as well as atoms and other electrons in the material. On the basis of the film footage, they could even distinguish different phases within this ultrashort period. First, the irradiated electrons absorbed the light energy of the photons in the graphite, transforming photonic energy into electrical energy. Then the energy was distributed to other electrons, before they passed it on to the surrounding atoms. In the final process, the electrical energy was converted into heat, warming up the graphite.

The special camera used to film how the light energy was distributed through the electronic structure — according to the researchers, one of the world’s fastest — has a temporal resolution of 13 fs. “Thanks to the extremely short duration of light pulses used, we are able to film ultrafast processes live. Our investigations have shown that there is a surprising amount of stuff happening here,” said professor Michael Bauer. Bauer and his team developed the camera system with professor Kai Roßnagel and his group.

Filming the motion of electrons using an ultrafast camera, Kiel University.

With its ultrafast light rays, the Kiel system is one of the fastest and most powerful in the world. Courtesy of Jürgen Haacks, CAU.

The experiments confirm theoretical predictions and enable a new perspective on an area of research that has hardly been investigated on such a short timescale. “Through our new technical possibilities, these fundamental, complex processes can be observed directly for the first time,” Bauer said. In the future, this approach could be applied to investigate and optimize ultrafast motions of light-agitated electrons in materials with promising optical properties. A better understanding of the processes involved in the conversion of light into electricity could be important for future applications in ultrafast optoelectronic components.

The research was published in Physical Review Letters ( 


Published: December 2018
Optoelectronics is a branch of electronics that focuses on the study and application of devices and systems that use light and its interactions with different materials. The term "optoelectronics" is a combination of "optics" and "electronics," reflecting the interdisciplinary nature of this field. Optoelectronic devices convert electrical signals into optical signals or vice versa, making them crucial in various technologies. Some key components and applications of optoelectronics include: ...
Graphene is a two-dimensional allotrope of carbon consisting of a single layer of carbon atoms arranged in a hexagonal lattice pattern. It is the basic building block of other carbon-based materials such as graphite, carbon nanotubes, and fullerenes (e.g., buckyballs). Graphene has garnered significant attention due to its remarkable properties, making it one of the most studied materials in the field of nanotechnology. Key properties of graphene include: Two-dimensional structure:...
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