Solar technology: Innovative, efficient light-collecting system

27.06.2024

Würzburg researchers from the Bavarian Solar Technologies Go Hybrid network are reporting progress on the road to more efficient utilisation of solar energy: they have developed an innovative light collection system.

Die Strukturformeln der vier Merocyanin-Farbstoffe (links), die in gestapelter Anordnung (rechts) das neue Lichtsammelsystem URPB ergeben.
The structural formulae of the four merocyanine dyes (left), which in stacked arrangement (right) form the new URPB light-harvesting system. (Image: Alexander Schulz / University of Würzburg) (Image: Alexander Schulz / Universität Würzburg) (Bild: Alexander Schulz / Universität Würzburg)

In order to convert sunlight into electricity or other forms of energy as effectively as possible, the very first step is to have an efficient light collection system. Ideally, this should be panchromatic, i.e. absorb the entire spectrum of visible light.

The light-collecting antennae of plants and bacteria are a model for this. These capture a broad spectrum of light for photosynthesis, but are very complex in structure and require many different dyes to transmit the energy of the absorbed light and focus it on a central point.

The light-collecting systems developed by humans to date also have disadvantages:

Although inorganic semiconductors such as silicon are panchromatic, they only absorb light weakly. In order to absorb enough light energy, very thick layers of silicon down to the micrometre range are therefore required - making solar cells relatively bulky and heavy.

Organic dyes that are suitable for solar cells are much thinner: their layer thickness is only around 100 nanometres. However, they are barely able to absorb a broad spectral range and are therefore not particularly efficient.

Thin layer absorbs a lot of light energy

Researchers at Julius-Maximilians-Universität (JMU) Würzburg have now presented an innovative light-collecting system in the journal Chem that differs significantly from previous systems.

"Our system has a band structure similar to that of inorganic semiconductors. This means that it absorbs light panchromatically across the entire visible range. And it uses the high absorption coefficients of organic dyes. As a result, it can absorb a great deal of light energy in a relatively thin layer, similar to natural light-collecting systems," says JMU chemistry professor Frank Würthner. His team from the Institute of Organic Chemistry / Centre for Nanosystems Chemistry designed the light-harvesting system at JMU and researched it together with Professor Tobias Brixner's group from the Institute of Physical and Theoretical Chemistry.

Four colourants in an ingenious arrangement

Put simply, the innovative light-collecting antenna from Würzburg consists of four different merocyanine dyes that are folded and stacked closely together. The ingenious arrangement of the molecules enables ultra-fast and efficient energy transport within the light antenna.

The researchers have given the prototype of the new light-collecting system the name URPB. The letters stand for the light wavelengths that are absorbed by the four dye components of the antenna: U for ultraviolet, R for red (red), P for purple (violet), B for blue (blue).

Performance verified via fluorescence

The researchers have demonstrated that their novel light-collecting system works so well by measuring the so-called fluorescence quantum yield. This involves measuring how much energy the system emits in the form of fluorescence. This allows conclusions to be drawn about the amount of light energy that it has previously collected.

The result: the system converts 38 per cent of the light energy irradiated over a broad spectral range into fluorescence - the four dyes alone, on the other hand, manage less than one per cent to a maximum of three per cent. The right combination and skilful spatial arrangement of dye molecules in the stack therefore make a big difference.


Publication

Panchromatic Light-Harvesting Antenna by Supramolecular Exciton Band Engineering for Heteromeric Dye Foldamer. Alexander Schulz, Rebecca Fröhlich, Ajay Jayachandran, Franziska Schneider, Matthias Stolte, Tobias Brixner, and Frank Würthner. Chem, 26. June 2024, Open Access https://doi.org/10.1016/j.chempr.2024.05.023

Contact

Prof. Dr. Frank Würthner, Institute of Organic Chemistry, Center for Nanosystems Chemistry, University Würzburg, wuerthner@uni-wuerzburg.de

Website Center for Nanosystems Chemistry

 

By Robert Emmerich

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