Electron Storage Ring BESSY II
BESSY II generates bright light for researching energy and materials
BESSY II is a third-generation synchrotron radiation source that produces extremely bright X-ray light. Researchers from all over the world can use this light for their experiments. BESSY II is a universal tool for studying an endless variety of samples, for example solar cells, materials for solar hydrogen production and quantum materials. Proteins can be studied for the development of new medicines, and meteorites and archaeological finds can be investigated using the soft X-ray light from BESSY II.
BESSY II is THE soft X-ray synchrotron in Germany
With its focus on soft X-rays, BESSY II is unique in Germany. In this sense, the facility is the complement to PETRA III of DESY in Hamburg, which serves the hard X-ray spectrum. More than 1400 guest researchers use BESSY II each year, and appreciate the high reliability and stability of the photon source. The users work on some 50 beamlines, each of which offers the latest methods in spectroscopy and microscopy. BESSY II has an outstanding international reputation for its method development.
Strong in partnership
HZB has strong partners engaged in the continual advancement of BESSY II. Strategic partners include the Max Planck Society, the Bundesanstalt für Materialforschung (BAM) and the Physikalisch-Technische Bundesanstalt (PTB) as well as many research groups at universities, all of whom are forever contributing new ideas.
Optimal conditions for time-resolved experiments
BESSY II furthermore offers extremely exciting possibilities for time-resolved experiments. With the development of low-alpha mode, researchers can study materials with very short light pulses (2 picoseconds). The femtoslicing source at BESSY II is the most successful of its kind in the world. Currently, HZB is using this long-standing experience in time-resolved experimentation to accomplish a worldwide unique upgrade of BESSY II.
BESSY VSR: Short and long light pulses
By 2023, BESSY II will have been upgraded into a variable pulse length storage ring. In future, for each experiment, researchers will be able to choose between short light pulses (1.5 picoseconds) and longer light pulses (15 picoseconds) – without any loss in light intensity. That does not exist at any other synchrotron source in the world.