All BESSY II instruments reconnected to the network
© HZB / D. Laubner
Thirteen months ago, HZB fell victim to a criminal cyberattack that also took BESSY II light source and the instruments in the experimental hall out of operation. BESSY II was up and running again after just three weeks and the instruments were gradually put back into operation. Now HZB can report some good news: All experimental stations are again integrated into the new IT networks and can record data.
In a task force led by Andreas Jankowiak and Jens Viefhaus, a team led by Ruslan Ovsyannikov succeeded in implementing a new IT infrastructure and a resilient network architecture. This project is now to be firmly established and perpetuated at HZB. The aim is to achieve the full functionality of the BESSY-II user service, to establish new possibilities for remote experiments and better data management.
The project also benefits from the successes of an international cooperation that is developing a new basis for experimental data management at light sources and small labs called Bluesky. With Bluesky, a new type of experimental data acquisition system is being introduced throughout BESSY II (under the leadership of HZB employees William Smith and Simone Vadilonga). It is already in operation at several BESSY beamlines. The introduction of Bluesky at BESSY II is a milestone and has attracted much attention in the scientific community. Several European accelerators are interested in the novel data control system.
HZB is also participating in the Helmholtz project ROCK-IT (Remote, Operando Controlled, Knowledge-driven, and IT-based) to meet the future challenges of data management and the IT structures of large-scale scientific research facilities. The aim is to develop all necessary tools for the automation and remote access of in-situ and operando experiments at synchrotrons. Simplified access to the experiments is a central concern of the user community.
- Synchrotron radiation sources: toolboxes for quantum technologiesSynchrotron radiation sources generate highly brilliant light pulses, ranging from infrared to hard X-rays, which can be used to gain deep insights into complex materials. An international team has now published an overview on synchrotron methods for the further development of quantum materials and technologies in the journal Advanced Functional Materials: Using concrete examples, they show how these unique tools can help to unlock the potential of quantum technologies such as quantum computing, overcome production barriers and pave the way for future breakthroughs.
- Peat as a sustainable precursor for fuel cell catalyst materialsIron-nitrogen-carbon catalysts have the potential to replace the more expensive platinum catalysts currently used in fuel cells. This is shown by a study conducted by researchers from the Helmholtz-Zentrum Berlin (HZB), Physikalisch-Technische Bundesanstalt (PTB) and universities in Tartu and Tallinn, Estonia. At BESSY II, the team observed the formation of complex microstructures within various samples. They then analysed which structural parameters were particularly important for fostering the preferred electrochemical reactions. The raw material for such catalysts is well decomposed peat.
- Helmholtz Investigator Group on magnonsDr Hebatalla Elnaggar is setting up a new Helmholtz Investigator Group at HZB. At BESSY II, the materials scientist will investigate so-called magnons in magnetic perovskite thin films. The aim is to lay the foundations for future terahertz magnon technology: magnonic devices operating in the terahertz range could process data using a fraction of the energy required by the most advanced semiconductor devices, and at speeds up to a thousand times faster.