• 9/26/2023
  • Reading time 3 min.

Organic dyes accelerate transport of buffered solar energy

How organic solar cells could become significantly more efficient

The sun sends enormous amounts of energy to the earth. Nevertheless, some of it is lost in solar cells. This is an obstacle in the use of organic solar cells, especially for those viable in innovative applications. A key factor in increasing their performance: Improved transport of the solar energy stored within the material. Now a research group at the Technical University of Munich (TUM) has shown that certain organic dyes can help build virtual highways for the energy.

Prof. Frank Ortmann (right) and Maximilian Dorfner discuss how specific molecules can increase the efficiency of organic solar cells. S. Reiffert / TUM
Prof. Frank Ortmann (right) and Maximilian Dorfner discuss how specific molecules can increase the efficiency of organic solar cells.

Organic solar cells are light, extremely thin energy collectors and as a flexible coating are a perfect fit on almost any surface: Solar cells based on organic semiconductors open up a range of application possibilities, for example, as solar panels and films which can be rolled up, or for use on smart devices. But one disadvantage in many applications is the comparatively poor transport of the energy collected within the material. Researchers are investigating the elementary transport processes of organic solar cells in order to find ways to improve this transport.

Stimulating sunlight

One of these researchers is Frank Ortmann, Professor of Theoretical Methods in Spectroscopy at TUM. He and his colleagues from Dresden focus more than anything on the mutual interaction between light and material – especially the behavior of what are called excitons. "Excitons are something like the fuel of the sun, which has to be used optimally," explains Ortmann, who is also a member of the "e-conversion" Excellence Cluster. "When light energy in the form of a photon collides with the material of a solar cell it is absorbed and buffered as an excited state. This intermediate state is referred to as an exciton." These charges cannot be used as electrical energy until they reach a specially designed interface. Ortmann and his team have now shown that what are referred to as exciton transport highways can be created using organic dyes.

Turbocharger dyes

The reason it is so important that the excitons reach this interface as quickly as possible has to do with their short lifespan. "The faster and more targeted the transport, the higher the energy yield, and thus the higher the efficiency of the solar cell," says Ortmann. The molecules of the organic dyes, referred to as quinoid merocyanines, make this possible, thanks to their chemical structure and their excellent ability to absorb visible light. Accordingly, they are also suitable for use as the active layer in an organic solar cell, Ortmann explains.

Energy packets in the fast lane

Using spectroscopic measurements and models the researchers were able to observe the excitons racing through the dye molecules. "The value of 1.33 electron volts delivered by our design is far above the values found in organic semiconductors – you could say the organic dye molecules form a kind of super-highway," Ortmann adds. These fundamental new findings could pave the way for targeted, more efficient exciton transport in organic solid matter, accelerating the development of organic solar cells and organic light emitting diodes with even higher performance.


Directed Exciton Transport Highways in Organic Semiconductors
Kai Müller, Karl S. Schellhammer, Nico Gräßler, Bipasha Debnath, Fupin Liu, Yulia Krupskaya, Karl Leo, Martin Knupfer, Frank Ortmann
DOI: 10.1038/s41467-023-41044-9

Further information and links
  • Researchers from the Technical University of Munich, the TU Dresden and the Leibniz Institute for Solid State and Materials Research Dresden were involved in the project.
  • The "e-conversion" cluster researches the fundamental processes involved in the conversion of regenerative energies, such as photovoltaics, photocatalysis and batteries. The researchers are working to reduce energy losses caused by physical effects at interfaces between different materials. These are crucial for the efficiency of energy conversion. www.e-conversion.de

Technical University of Munich

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Contacts to this article:

Prof. Frank Ortmann
Technical University of Munich
Professorship of Theoretical Methods in Spectroscopy
Phone: +49 (89) 289 - 13611
frank.ortmannspam prevention@tum.de

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