Solar cells on moon glass for a future base on the moon
Components of a Moon solar cell. © Felix Lang.
Future settlements on the moon will need energy, which could be supplied by photovoltaics. However, launching material into space is expensive – transporting one kilogram to the moon costs one million euros. But there are also resources on the moon that can be used. A research team led by Dr. Felix Lang of the University of Potsdam and Dr. Stefan Linke of the Technical University of Berlin have now produced the required glass from ‘moon dust’ (regolith) and coated it with perovskite. This could save up to 99 percent of the weight needed to produce PV modules on the moon. The team tested the radiation tolerance of the solar cells at the proton accelerator of the HZB.
“The highlight of our study is that we can extract the glass we need for our solar cells directly from the lunar regolith without any processing,” says project leader Felix Lang, who leads a junior research group at the Institute of Physics and Astronomy, funded by a Freigeist-Fellowship of the VolkswagenStiftung.
The solar cells tested by the researchers have a layered structure, with the substrate and cover layer consisting of Moon glass and the intermediate layer of perovskite. “These solar cells require ultrathin absorber layers of 500 to 800 nanometers only, allowing the fabrication of 400 square meter solar cells with just one kilogram of perovskite raw material brought from Earth,” Lang summarizes.
Lang emphasizes the amazing stability of the solar cells produced against solar and cosmic radiation – an essential prerequisite for a stable energy supply on the moon. The radiation tolerance was tested at the Proton accelerator at HZB in the team of Prof. Andrea Denker.
Read the full text at the website of University of Potsdam:
https://www.uni-potsdam.de/en/headlines-and-featured-stories/detail/2025-04-03-solarzellen-auf-mondglas-photovoltaik-koennte-die-energie-fuer-eine-zukuenftige-basis-au
- Scrolls from Buddhist shrine virtually unrolled at BESSY IIThe Mongolian collection of the Ethnological Museum of the National Museums in Berlin contains a unique Gungervaa shrine. Among the objects found inside were three tiny scrolls, wrapped in silk. Using 3D X-ray tomography, a team at HZB was able to create a digital copy of one of the scrolls. With a mathematical method the scroll could be virtually unrolled to reveal the scripture on the strip. This method is also used in battery research.
- Long-term test shows: Efficiency of perovskite cells varies with the seasonScientists at HZB run a long-term experiment on the roof of a building at the Adlershof campus. They expose a wide variety of solar cells to the weather conditions, recording their performance over a period of years. These include perovskite solar cells, a new photovoltaic material offering high efficiency and low manufacturing costs. Dr Carolin Ulbrich and Dr Mark Khenkin evaluated four years of data and presented their findings in Advanced Energy Materials. This is the longest series of measurements on perovskite cells in outdoor use to date. The scientists found that standard perovskite solar cells perform very well during the summer months, even over several years, but decline in efficiency during the darker months.
- Sodium-ion batteries: New storage mechanism for cathode materialsLi-ion and Na-ion batteries operate through a process called intercalation, where ions are stored and exchanged between two chemically different electrodes. In contrast, co-intercalation, a process in which both ions and solvent molecules are stored simultaneously, has traditionally been considered undesirable due to its tendency to cause rapid battery failure. Against this traditional view, an international research team led by Philipp Adelhelm has now demonstrated that co-intercalation can be a reversible and fast process for cathode materials in Na-ion batteries. The approach of jointly storing ions and solvents in cathode materials provides a new handle for designing batteries with high efficiency and fast charging capabilities. The results are published in Nature Materials.