Subcycle Nano-Optics Group - Universit?t Regensburg_bwin娱乐

Probing ultrafast dynamics on the nanoscale

Go to Research for an overview of what we are interested in

The Group

From left to right: Martin Waibel, Jakob Schlosser, Fabian Mooshammer, Ziheng Yuan (Photo: Julia Dragan / UR)

Inauguration of the RUN

Click here for more details

Open positions

We are hiring Master & Bachelor students as well as student assistents. Please check out the job advertisement and send an email to Dr. Fabian Mooshammer for further details.

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Many of the optical and electronic properties of solids are caused by extremely fast dynamics of electrons on the femtosecond (1 fs = 10^-15 s) time scale. Our main interest is to trace ultrafast processes, while resolving the impact of interfaces, strong light-matter coupling, or local structural changes on the nanometer (1 nm = 10^-9 m) length scale. We are developing new methods to effectively capture nano-femto-dynamics, allowing us to record nanoscopic slow-motion pictures.
Click on the image above or check our Research page for more information on our current work.

LATEST NEWS

New Members Join the Team

Photo: Julia Dragan / UR

A warm welcome to our new PhD students Jakob Schlosser & Ziheng Yuan as well as our Master student Martin Waibel!

Inauguration of the RUN

The opening of the Regensburg Center for Ultrafast Nanoscopy (RUN) has been celebrated with an inauguration event and an interdisciplinary symposium.

For more details, see RUN newsroom.

Press release UR (German): here.
Press folder UR (German): here.
Press release Bavarian State Ministry (German): here.

FUNDING

The group receives funding from the Bavarian State Ministry of Science and the Arts and the Elite Network of Bavaria for six years.

Press release (UR) in German.

Press release (ENB) in German.

The central goal of the research project "Nano-femto-control of cooperative dynamics in van der Waals quantum materials" is to probe and control strong electronic correlations and pronounced collective excitations on their intrinsic femtosecond temporal and nanometer spatial scales. During the six-year funding period, the group will thus, for example, shed light onto tailored phase transitions in heterostructures of atomically thin van der Waals crystals.