Modernisation of BESSY II+ light source
Antje Vollmer is spokeswoman for BESSY II and project lead of the BESSY II+ project. She says: "BESSY II is rising to the scientific and societal challenges. The positive feedback from users encourages us in this!" © HZB/M. Setzpfandt
The 16th edition of the BESSY@HZB user meeting will take place on 11-12 December 2024 in Berlin-Adlershof. 400 participants exchange information about research at BESSY II. This year, Romania is the country of honour. © HZB/M. Setzpfandt
The focus of the User Meeting 2024: Helmholtz-Zentrum Berlin (HZB) presents the BESSY II+ upgrade programme. It enables world-class research at BESSY II to be further expanded and new concepts to be tested with regard to the successor source BESSY III.
Every year in December, HZB invites the users of BESSY II light source to Adlershof for an exchange of expertise. Research highlights of the year are presented and the wishes of the user community regarding future developments are discussed.
"BESSY II is now in its 27th year of operation," says Antje Vollmer, BESSY II spokesperson. "The expectations of our users have changed over the years. They want additional infrastructures, laboratories close to the beamlines and have high expectations of the sample environment. Research interests have also changed. For example, we are seeing a strong interest in battery research and energy conversion processes."
This is where the BESSY II+ project comes in. The aim is for BESSY to become an "operando synchrotron for the energy transition".
A bridge to the future: the BESSY II+ project
BESSY II+ offers new experimental possibilities, especially for operando investigations. These make it possible, for example, to watch batteries or solar cells "at work". In addition to the new "operando" possibilities, the BESSY II+ project also focuses on the two topics of "modernisation" and "sustainability". Sustainability involves, among other things, the utilisation of waste heat from the BESSY II experimental hall. Machine learning and artificial intelligence will also be even more integrated into many processes.
Funding of BESSY II+
As part of the modernisation project, the HZB has received additional funding from the Ministry of Education and Research (BMBF). "Invest BESSY II+" covers the most important investments for the project, which the BMBF is supporting to the tune of 17.45 million euros. This funding secures the development of new infrastructures, such as the SoTeXS instrument, which stands for soft-to-tender X-ray spectroscopy. This is a comprehensive concept for operando, metrological, multi-modal experiments that will be of great benefit to research into batteries and materials for energy applications.
Antje Vollmer emphasises: "BESSY II is facing up to the scientific and social challenges. The positive feedback from users encourages us to do so!"
- Less is more: Why an economical Iridium catalyst works so wellIridium-based catalysts are needed to produce hydrogen using water electrolysis. Now, a team at HZB has shown that the newly developed P2X catalyst, which requires only a quarter of the Iridium, is as efficient and stable over time as the best commercial catalyst. Measurements at BESSY II have now revealed how the special chemical environment in the P2X catalyst during electrolysis promotes the oxygen evolution reaction during water splitting.
- Ultrafast dissociation of molecules studied at BESSY IIFor the first time, an international team has tracked at BESSY II how heavy molecules – in this case bromochloromethane – disintegrate into smaller fragments when they absorb X-ray light. Using a newly developed analytical method, they were able to visualise the ultrafast dynamics of this process. In this process, the X-ray photons trigger a "molecular catapult effect": light atomic groups are ejected first, similar to projectiles fired from a catapult, while the heavier atoms - bromine and chlorine - separate more slowly.
- Battery research with the HZB X-ray microscopeNew cathode materials are being developed to further increase the capacity of lithium batteries. Multilayer lithium-rich transition metal oxides (LRTMOs) offer particularly high energy density. However, their capacity decreases with each charging cycle due to structural and chemical changes. Using X-ray methods at BESSY II, teams from several Chinese research institutions have now investigated these changes for the first time with highest precision: at the unique X-ray microscope, they were able to observe morphological and structural developments on the nanometre scale and also clarify chemical changes.