September 16, 2022
4 MIN READ
The goal of the energy revolution in Germany is to cover the private and industrial energy demand from renewable energies by 2045. The tense situation in Europe shows that this is beneficial for both the environment and the self-sufficiency of the entire European Union economy in general. The task is therefore to promote the generation of electricity from wind, water, and sun.
One of the leading energy research and development institutes in Europe is the Center for Solar Energy and Hydrogen Research (Zentrum für Sonnenenergie - und Wasserstoff-Forschung Baden-Württemberg [ZSW]) based in Stuttgart. The ZSW is dedicated to this very goal of achieving a 100% energy supply from renewables in Germany by 2045.
If renewable energies are weighted according to their availability, solar technology is considered core. Simply because the radiant power of the sun can be planned better than the power of the wind. An extra benefit is that solar power plants can be deployed in a decentralized way, i.e., away from the coasts in offshore wind farms or tidal power plants throughout Germany.
In addition to expanding the areas for solar parks, on the roofs of houses, etc., it is also important to increase the efficiency of each individual solar cell. In other words, to absorb more light from the incident sunlight.
The challenge: A conventional silicon solar cell reaches its theoretical performance limit at an efficiency of 29% (Shockley-Queisser Limit). This means that a maximum of 29% of the incident light energy can be converted into electricity.
This natural limit of silicon could be overcome with a tandem solar cell.
In promising tests performed by researchers at the CSEM and EPFL, nearly 31.25% efficiency could be achieved with a tandem solar cell. Tandem solar cells are characterized by the fact that they use two absorber materials with different bandgaps which absorb the different spectral ranges of the solar spectrum and thus use it in a more efficient way. This leads to a significant cost reduction for each KWh produced. Also note that organometallic halides, such as methylammonium iodide are typically used.
At this point however, ZSW reached its limits with its own technical equipment because working with perovskite can quickly lead to unwanted chemical reactions such as chemical burns. For this reason, a partner from the industry was sought who could demonstrate years of experience in plant construction and vacuum expertise.
This is how the cooperation between ZSW and Leybold started. ZSW is an expert in solar technology and Leybold is an expert in high vacuum thin-film coatings and all systems are equipped with vacuum components developed in-house.
The goal of this collaboration: create an experimental vacuum setup so that hypotheses surrounding the mode of action of the tandem solar cell can be tested as quickly as possible. For this purpose, four process chambers with different coating methods have been built and installed. This was an exciting challenge since most systems in plant engineering only require one process chamber.
The UNIVEX series comprises multi-purpose coating systems for the production of functional PVD coatings. Features such as modular design, variable chamber sizes and numerous accessories make the coating systems more flexible. Over the past 50 years, Leybold has installed over 800 of these unique systems worldwide.
The necessary functional scope for this task is provided by the Leybold UNIVEX C 900, which has been customized to match the needs of the ZSW.
In general, two overriding uses of the systems can be derived:
The following coating methods can be carried out in the four chambers:
For reasons of safety, timesaving as well as protecting the materials from water (which is present in ambient air), it is possible to operate the system completely in a vacuum thanks to two additional chambers:
The evaporation of perovskite solar cells is a key application for future technologies and renewable energies. In addition to the further development of these specific processes, a long-term partnership is envisaged between ZSW and Leybold, which is regularly joining forces with various teams from this and other institutes to collaborate on new projects.
Once set up, the UNIVEX C 900 enables fully automated process control with highly reproducible results. We are confident that the ZSW will use the UNIVEX system to increase knowledge through high experimentation density and that together we contribute to the successful energy transition.
We look forward for ZSW and many other research institutes to support the world’s energy transition. We strongly believe we can only master this radical transformation by working together.