High-performance solar cells: physicists from Halle grow stable perovskite layers
Perovskites are currently receiving a great deal of attention in the solar industry. In 2009, researchers were first able to prove that organic-inorganic compounds with a special perovskite crystal structure are good absorbers that can effectively convert sunlight into electricity. Within just a few years, the efficiency of perovskite solar cells was increased to well over 20 percent in the laboratory.
“Although modern, monocrystalline silicon solar cells achieve slightly better values, they are much harder to manufacture and they have been under development for a much longer time,” says Dr Paul Pistor, a physicist at MLU and lead author of the study. Currently, however, there are no market-ready perovskite-based solar cells as there is no established process for the large-scale production of perovskites.
In addition, the thin crystal layers are rather unstable and sensitive to environmental influences. “High temperatures or humidity cause the perovskites to decompose and lose their ability to convert sunlight into electricity,” says Pistor. Yet, solar cells have to withstand elevated temperatures because they are permanently exposed to the sun.
In their study, the physicists from Halle investigated a special, inorganic perovskite consisting of caesium, lead and bromine or iodine. Instead of using the usual wet-chemical processes to produce the perovskites, they deployed a process that is already widely used in industry to produce thin layers and a range of components.
In a vacuum chamber, precursor materials are heated up until they evaporate. Then, the perovskite condenses on a colder glass substrate and a thin crystalline layer grows. “The advantage of this method is that every part of the process can be very well controlled. This way, the layers grow very homogenous and the thickness and composition of the crystals can be easily adjusted,” explains Pistor.
His team was thus able to produce perovskite layers based on caesium that didn’t decompose until they reached temperatures of 360 degrees Celsius. Using cutting-edge X-ray analysis, the researchers also analysed the growth and decay processes of the crystals in real time.
The results provide important insights into the underlying properties of perovskites and point to a process that may be suitable for the industrial realisation of modern perovskite-based solar cell technology.
Burwig T., Fränzel W., Pistor P., Crystal Phases and Thermal Stability of Co-evaporated CsPbX3 (X = I, Br) Thin Films, Journal of Physical Chemistry Letters (2018), doi: 10.1021/acs.jpclett.8b02059
Media Contact
More Information:
http://www.uni-halle.deAll latest news from the category: Physics and Astronomy
This area deals with the fundamental laws and building blocks of nature and how they interact, the properties and the behavior of matter, and research into space and time and their structures.
innovations-report provides in-depth reports and articles on subjects such as astrophysics, laser technologies, nuclear, quantum, particle and solid-state physics, nanotechnologies, planetary research and findings (Mars, Venus) and developments related to the Hubble Telescope.
Newest articles
Iron-Nickel-Zirconium Alloy Trigger a New Superconductor Zirconide
Student project uncovers superconductivity in polycrystalline iron nickel zirconide Zirconide: A New Transition Metal Tokyo, Japan – Researchers from Tokyo Metropolitan University have discovered a new superconducting material. They combined…
Heart of the Matter: Effective Anti-Obesity Strategies to Protect Cardiovascular Health
People with pockets of fat hidden inside their muscles are at a higher risk of dying or being hospitalised from a heart attack or heart failure, regardless of their body…
CO2 and Global Warming: How Soils and Plants Challenge Future Droughts
What will the future of our soils – and thus also the availability of water – look like under the influence of imminent climatic changes? An international study led by…