To Investigate the Interaction between UV Light and Matter

With the ERC Starting Grant, Birgitta Schultze-Bernhardt can bring particularly powerful laser sources and expensive high-power amplifiers to Graz. (Source: TU Graz, Lunghammer)

Ultraviolet light is particularly high-energy light. Its interaction with matter is of enormous importance, since our sun, for example, emits light in the UV range that triggers chemical reactions in atmospheric trace gases. So far, however, there is still no laser that emits directly in this high-energy range – something that would enable the direct access for research work in the ultraviolet spectral region. “In order to be able to investigate processes triggered by UV light as precisely as possible, we currently have to resort to tricks that are unfortunately very inefficient,” explains Birgitta Schultze-Bernhardt.

The researcher converts light from an infrared laser into UV light. Then two of these high-energy light sources are sent through a material sample in the form of so-called frequency combs. A frequency comb is a very stable short pulse laser that emits many millions of pulses per second. Inside the material, the frequencies are ‘swallowed’ to varying degrees. Finally, the use of two frequency combs makes it possible to measure the high optical frequencies very accurately using a conventional photodiode. This allows insights into the chemical components as well as the optical properties of materials.

For this concept, Schultze-Bernhardt was recently awarded the START Prize of the Austrian Science Fund FWF. Unfortunately, a lot of power is lost during this light conversion process. “To ensure that there is enough left over when converting from infrared to ultraviolet light, you have to start with a lot of power,” says Schultze-Bernhardt. “With current laser technology, only measurements in the near UV spectral range are possible.”

Schultze-Bernhardt received her doctorate at the faculty of physics at Munich University and at the Max Planck Institute for Quantum Optics under Nobel Prize winner Theodor W. Hänsch. (Source: TU Graz, Lunghammer)

The ERC Starting Grant of 2.2 million euros from the European Research Council ERC now enables the researcher to penetrate into the higher-energetic extreme UV range.

Making UV light ‘visible’

With the funds, Schultze-Bernhardt can, on the one hand, establish her own research group at the Institute of Experimental Physics and the Institute of Materials Physics and, on the other hand, bring particularly powerful laser sources and expensive high-power amplifiers to TU Graz. “This will enable us to achieve spectral resolutions in the future that would never be possible with current spectrometers and to transfer our method to UV ranges that have not been investigated satisfactorily so far.”

Although this is still basic research, Birgitta Schultze-Bernhardt is already thinking ahead with her work: “One area of application is atmospheric research. Maybe we can leave the lab at some point and move the measurements into the field. Colleagues of ours are already working on making the technology portable.” Cooperation with other institutes of TU Graz, such as the Institute of Electrical Measurement and Sensor Systems, is also being planned. Together with Alexander Bergmann, head of the institute, Schultze-Bernhardt would like to investigate the formation of aerosols in atmospheric trace gases in more detail. (Source: TU Graz)

Further reading: Capturing the Spectral Fingerprint – START Prize 2020 for TU Graz physicist Birgitta Schultze-Bernhardt,, 30th June 2020

Link: Dual Comb Spectroscopy (B. Schultze-Bernhardt), Institut of Experimental Physics, Graz University of Technology, Graz, Austria


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