Rolling out solar cells: German-Danish project researches flexible organic energy technologies

The development of organic energy technologies has already been researched for several years, since solar cells and LEDs made of organic materials have great potential regarding energy efficiency and sustainable power generation.

The reason for this is their completely new properties in comparison with traditional silicon cells: mechanical flexibility, light weight, low costs, as well as semi-transparency. In this way, innovative applications for the future could be possible, right up to smart windows or wearable technologies in clothing.

Efficient and cheap solar cells

With the trans-regional research project “RollFlex”, German and Danish scientists want to make great strides in the development of organic energy technology. For this purpose, the RollFlex Innovation Project Centre is being created in the Danish town of Sonderborg, as a laboratory for researching and developing roll-to-roll printing presses. Using this process, materials should be printed onto large areas of thin substrates such as flexible glass or plastic films.

In the end, they should also include electrical components such as flexible electronics, organic light emitting diodes (OLEDS) and solar cells. They could then be used to develop products for areas like lighting, displays or photovoltaic applications. In the cleanroom of the CAU, Kiel scientists investigate nano and micro structures, to increase the efficiency of organic solar cells and OLEDs.

“Through the RollFlex project, we can bundle excellent competencies from the region in the areas of roll-to-roll printing and optimisation of organic components. In building up a strong network between southern Denmark and northern Germany, we hope to make energy technology significantly more efficient in the long term. Kiel Nano Laboratory’s cleanroom makes an important contribution here,” said Martina Gerken, Professor at the Institute of Electrical Engineering and Information Technology and the project leader at the CAU.

Kiel team produces nano and micro structures in cleanroom

The Kiel partners in the project research the central principles of the new solar technology: by using small components they want to demonstrate how micro and nano structures can increase the efficiency of flexible solar cells. For this purpose, electrical engineers from the CAU will initially investigate how the individual structures influence the luminosity of OLEDs. “Because the principle of OLEDs is similar to how solar cells work – just in reverse,” explained the head of the laboratory, Dr. Sabrina Jahns. “To transfer the results which we obtain from the small centimetre-sized OLEDs and organic solar cells to large roll-out components – that is the greatest challenge for our research project.”

The small size of the components makes it relatively easy to experiment with numerous variants. In this way, the scientists want to identify the optimal configuration for the solar cells which are to be produced. In their optical laboratory, the scientists from Kiel irradiate the OLEDs with lasers, to investigate the effectiveness of the applied micro and nano structures. The small solar cells and OLEDs are developed in the cleanroom laboratory in Kiel, which offers ideal conditions for producing sensitive prototypes without impurities.

The scientists at the CAU are working in close cooperation with FUMT R&D Functional Materials GmbH, a start-up founded at Kiel University to develop functional materials. In particular, special sheets with nano particles are produced for the project there. They should protect the OLEDs – and later also the organic solar cells – from humidity and oxygen. “This protective layer is particularly important for organic technologies. It prevents chemical processes which can shorten the lifespan of solar cells and OLEDs,” explained Dr. Ala Cojocaru, project leader at FUMT. “We have already gained experience with foils from another research project, for which we applied a functional layer by means of a roll-to-roll process. For us, it is very interesting to see how our materials can be used to produce energy,” added CEO Hartmut Schmidt-Niepenberg.

Embedded in university teaching and in the region

Both the CAU and SDU have integrated the joint research project into their teaching. “We thereby offer our students an excellent education, because they gain practical experience working in cutting-edge research,” Martina Gerken said. The regional joint research venture is also exciting for many businesses in the region of northern Germany and southern Denmark who already work with roll-to-roll technologies. “Organic solar cells have been researched for many years, but we’re now registering an increasing interest on the part of industry. The companies see an actual breakthrough nearing, in which the solar cells are so stable and efficient that they can be used commercially. So, for example, more companies from the vehicle industry are interested in this technology,” said Morten Madsen, project leader at SDU.

The RollFlex Innovation Project Centre is being funded from 2016-2019 by the EU subsidy programme Interreg Deutschland-Danmark with around 1.6 million Euros. Partner institutions involved are the SDU, CAU, FUMT R&D Functional Materials GmbH and Stensborg A/S. There are also many network partners in northern Germany and Denmark, including the Flensburg Chambers of Commerce and Industry (IHK Flensburg), the North German Initiative Nanotechnology Schleswig-Holstein e.V. (NINa SH), and the Business Development and Technology Transfer Corporation of Schleswig-Holstein (WTSH).

Further information is available at:
http://www.rollflex.eu
http://www.sebrochure.dk/Roll-Flex/WebView/

Photos are available to download:
http://www.uni-kiel.de/download/pm/2016/2016-422-1.jpg
In the long run, flexible solar cells could be produced on a large scale by roll-to-roll printing presses.
Photo/Copyright: NanoSYD

http://www.uni-kiel.de/download/pm/2016/2016-422-2.jpg
Due to their mechanical flexibility, organic light emitting diodes (OLEDs) can be applied to flexible foil. Added zinc oxide particles in the foil should increase the luminosity of the OLEDs.
Photo/Copyright: Matthias Bremer

http://www.uni-kiel.de/download/pm/2016/2016-422-3.jpg
Kiel Nano Laboratory’s cleanroom provides excellent conditions to build sensitive OLEDs without contaminations.
Photo/Copyright: Angelina Niepenberg

http://www.uni-kiel.de/download/pm/2016/2016-422-4.jpg
The scientists from Kiel irradiate OLEDs with lasers to test their properties. The results should be scaled up to large solar cells.
Photo/Copyright: Sabrina Jahns

http://www.uni-kiel.de/download/pm/2016/2016-422-5.jpg
An applied nano-mesh structure makes the foil shimmer. Using such a structure should enhance the performance of OLEDs and organic solar cells.
Photo/Copyright: Sabrina Jahns

http://www.uni-kiel.de/download/pm/2016/2016-422-6.jpg
Nanostructure elements on a foil that shall be produced in a roll-to-roll-printing process, here in a laboratory scale.
Photo/Copyright: Angelina Niepenberg

http://www.uni-kiel.de/download/pm/2016/2016-422-7.jpg
Scientists of Kiel University and FUMT, a CAU-based start-up, work closely together in the RollFlex project (from left): Sabrina Jahns, Martina Gerken (both CAU), Ana Cojocaru, Iris Hölken und Hartmut Schmidt-Niepenberg (both FUMT). Photo/Copyright: Siekmann, CAU

Contact:
Prof. Dr Martina Gerken
CAU Institute of Electrical Engineering and Information Technology
Integrated Systems and Photonics
Tel.: 0431 880 6250
E-mail: mge@tf.uni-kiel.de

Dr.-Ing. Sabrina Jahns
CAU Institute of Electrical Engineering and Information Technology
Integrated Systems and Photonics
Tel.: 0431 880 6255
E-mail: sja@tf.uni-kiel.de

Hartmut Schmidt-Niepenberg
FUMT R&D, CEO
Tel. 0431 7054186
E-mail: hsn@fumt-rd.de

Dr. Ala Cojocaru
FUMT R&D, Project Management
Tel. 0431 7054186
E-mail: ac@fumt-rd.de

Details, which are only a millionth of a millimetre in size: This is what the research focus “Kiel Nano, Surface and Interface Science – KiNSIS” at Kiel University has been working on. In the nano-cosmos, different laws prevail than in the macroscopic world – those of quantum physics. Through intensive, interdisciplinary cooperation between materials science, chemistry, physics, biology, electrical engineering, computer science, food technology and various branches of medicine, the research focus aims to understand the systems in this dimension and to implement the findings in an application-oriented manner. Molecular machines, innovative sensors, bionic materials, quantum computers, advanced therapies and much more could be the result.

More information at
http://www.kinsis.uni-kiel.de