Foto: Volker Lannert/Uni Bonn

Chemistry with physical methods

For her research, Jeannine Gleim studies supercritical chemical substances. It sounds more precarious than it actually is, yet it is spectacular all the same. A high-power laser is Jeannine's most important tool.

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Super-fast, super-precise, and super-modern – these words can sum up Jeannine Gleim's research at the Institute of Physical and Theoretical Chemistry. She wants to make chemical interactions visible as they are happening using state-of-the-art laser technology. In doing so, she moves on the border between physics and chemistry. Physics offer methods for measurement in the high-tech laser laboratory and chemistry the objects for examination with supercritical substances – also called fluids. They are called fluids because they can flow like liquids. These fluids are called supercritical because they are not really liquids. Their state of aggregation cannot be clearly assigned to the liquid or the gaseous state. And that is exactly what makes them so attractive.

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Molecules are not rigid entities. They are always in vibration. This is called oscillation. And that not only affects the molecule as a whole, but also its chemical bonds. Scientists can relatively easily measure the frequency with which the individual bonds vibrate. Jeannine used this knowledge for her master's thesis. With the help of infrared spectroscopy, Jeannine stimulated single bonds of a molecule. The infrared light used had exactly the same frequency as that of the bond. If she stimulated one bond, it affected the others within the same molecule, as well as the bonds between different molecules. What Jeannine found out is that in the supercritical phase, the mutual influence of the individual bonds of different molecules is weaker because the interactions between the molecules become weaker.

For her doctoral thesis at the Institute of Physical and Theoretical Chemistry, Jeannine goes one step further with the help of multidimensional infrared spectroscopy. The advantage is that Jeannine can simultaneously make several bonds oscillate and even observe the flow of energy within the molecule. Her high-power laser fires off super-short flashes of light that last only a few femtoseconds. A femtosecond is the trillionth part of a second - so incredibly fast that even the fastest chemical reactions or spontaneous movements of the molecule are almost frozen like in a photographic snapshot.

Jeannine is doing real pioneering work. Research with multi-dimensional infrared spectroscopy, also abbreviated as MDIR, still counts as fundamental research. But the potential is huge. Environmental technology, pharmaceutical industry, material science and even medicine could benefit from her work in the future. Similar high-resolution imaging techniques like MRI already exist, but MDIR has a decisive advantage - only it shows superfast interactions at the molecular level in real time.

1/12 Photo / Volker Lannert. A typical step in the chemistry lab. Accurate measurement of the samples is also part of everyday life for high-tech chemist Jeannine. Whether in solid… © Volker Lannert / Uni Bonn

2/12 ...or in liquid form. Goggles, gowns and a hood are imperative to the handling of the partly dangerous substances. 4-trans-methoxy-3-buten-2-on dissolved in Tetrachloroethylene is an exemplary object of investigation. Photo / Volker Lannert © Volker Lannert / Uni Bonn

3/12 Before Jeannine can analyze the substance, she first has to bring it into the sample cell. The solution is fitted between two window panes. Photo / Volker Lannert © Volker Lannert / Uni Bonn

4/12 Photo / Volker Lannert: The sample cell is then placed into the laser laboratory for the experiment. © Volker Lannert / Uni Bonn

5/12 Photo / Volker Lannert: The laser system delivers pulses at a repetition rate of one kilohertz and has a light output of six watts. At the same time, the pulses have a duration of 50 femtoseconds. This means, the pulsed light output of Jeannine's laser corresponds to one third of the electrical power of the world's nuclear power plants - admittedly in an unimaginably short time. The laser is also still colored. At a wavelength of 800 nanometers, the beam is red. © Volker Lannert / Uni Bonn

6/12 Photo / Volker Lannert: At the start of the experiment, Jeannine transforms the laser beam into infrared light, which is invisible to the human eye. A power meter, a colored auxiliary laser or even a simple piece of paper help with the adjustment. © Volker Lannert / Uni Bonn

7/12 Photo / Volker Lannert. And that is a mammoth task. More than 100 mirrors, screens and filters form a complex labyrinth of light trails that is impenetrable to the layman’s eye. © Volker Lannert / Uni Bonn

8/12 Photo / Volker Lannert. As well as brain work, a great deal of craftsmanship is also required. The many components must be designed to allow the light to reach the sample with the shortest route possible. © Volker Lannert / Uni Bonn

9/12 Photo / Volker Lannert. The optical components can be adjusted to the micrometer in all directions. Some components like this cube, fulfill another purpose - they split up the laser beam. © Volker Lannert / Uni Bonn

10/12 Photo / Volker Lannert. Two beams, both of which must have traversed the same path distance, form the basis for the infrared spectroscopy of Jeannine's master thesis. For the multidimensional spectroscopy of her doctoral thesis, she needs more rays than only two. For this Jeannine utilizes a trick that is already used by the frequency modulation radio (FM radio). This results in many light pulses that are correspondingly delayed and with which ultrafast processes are first examined. © Volker Lannert / Uni Bonn

11/12 Photo / Volker Lannert. In multidimensional infrared spectroscopy, a computer takes over the programmable generation of the many infrared rays by frequency modulation. A rotating chopper disc ensures that the signal is interrupted at certain intervals. These are coupled to the repetition rate of the laser and serve, in later analysis, to eliminate sources of interference. © Volker Lannert / Uni Bonn

12/12 Photo / Volker Lannert. By using mathematical calculations, in the evaluation the multidimensional signals obtained can be converted into a spatial structure of the molecules. This gives Jeannine a presentable result that she can discuss with her doctoral supervisor, Professor Dr. Peter Vöhringer. © Volker Lannert / Uni Bonn

Foto: Volker Lannert/Uni Bonn

Chemistry with physical methods

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