A record year for our living lab for building-integrated PV
© BAIP/HZB
In 2025, our solar facade in Berlin-Adlershof generated more electricity than in any of the previous four years of operation.
With about 32 MWh, the solar facade of our BIPV living laboratory produced enough electricity to power more than 12 average four-person households. Thanks to the energy-intensive research landscape at the Helmholtz-Zentrum Berlin, we can also consume all of the electricity generated on site at any time.
Even after five years of operation, our building-integrated solar modules show no measurable degradation. Differences in annual energy yield can so far be attributed exclusively to weather-related fluctuations. According to the German Weather Service, the duration of sunshine in 2025 was around 1,900 hours nationwide. In addition, the year was comparatively low in precipitation, which, together with the high duration of sunshine, explains the high solar yield.
However, we were particularly surprised by December: exceptionally good PV weather led to yields more than twice as high as in the previous year! Especially in spring, autumn and winter, the sun is more favourable for the solar facade, so we regularly observe higher yield peaks than in the summer months.
We are excited to see how this year will turn out.
- AI agents deliver results – but do they reason scientifically?A research team co-led by Kevin Maik Jablonka from the Helmholtz Institute for Polymers in Energy Applications Jena (HIPOLE Jena) and N. M. Anoop Krishnan from the Indian Institute of Technology Delhi has developed Corral, a new benchmark for AI agents in science. The preprint “AI scientists produce results without reasoning scientifically” has been published on arXiv (https://doi.org/10.48550/arXiv.2604.18805). The analysis shows that current systems can execute scientific workflows and deliver results; however, they often do not follow the basic principles of scientific testing and reasoning.
- Magnetic field during catalyst synthesis triples ammonia yieldApplying an external magnetic field during the synthesis of CoFe₂O₄ electrocatalysts triples the ammonia yield during electrocatalytic conversion. The magnetic field alters the surface states of the spinel oxide thin films, making catalytically active sites more accessible. In the journal 'Advanced Functional Materials', a team led by Marcel Risch at HZB and Sanjay Mathur at University of Cologne demonstrates a scalable strategy for developing next-generation electrocatalysts for efficient and sustainable chemical production.
- Materials chemistry shapes the future of catalysisThe synthesis of materials can serve as a tool for developing smart, adaptive electrocatalysts. This rapidly evolving field of research involves in-situ analytics, data-driven discoveries and autonomous robotics. These new approaches could accelerate the discovery of long-lasting and efficient catalysts for future energy conversion and the decarbonisation of the chemical industry. A recent article by Dr Prashanth Menezes and his team in the renowned journal Angewandte Chemie provides an overview of this research.