Godehard Wüstefeld receives the Horst Klein Research Prize
Dr. Godehard Wüstefeld was awarded the Horst Klein Research Prize.
© DPG
The prize was awarded on 21 March 2019 at the Spring Conference of the Deutsche Physikalische Gesellschaft by the Physikalischer Verein Frankfurt, the Department of Physics of the Goethe University Frankfurt and the Arbeitskreis Beschleunigerphysik (AKBP). © DPG
The physicist Dr. Godehard Wüstefeld was awarded the Horst Klein Research Prize at the annual conference of the German Physical Society. The award recognizes his outstanding scientific achievements in accelerator physics in the development of BESSY II and BESSY VSR.
Over the last thirty years, Dr. Godehard Wüstefeld has made decisive contributions to the further development of storage-ring-based synchrotron radiation sources. Thanks to its innovative concepts, the performance and application areas of storage rings have been consistently expanded. Wüstefeld participated in the development of BESSY II and the Metrology Light Source and implemented several innovations there.
"Low α" operating mode
For example, he was instrumental in enabling a so-called "Low α" operating mode. In this operating mode, short and intensive electron pulses can be generated in storage rings. The "Low α" operating mode has been implemented at BESSY II and the Metrology Light Source as well as at other national and international synchrotron radiation sources and is now available to a large user community. In addition, this mode produces intense and coherent terahertz radiation, which is extremely useful for certain research questions.
Upgrade BESSY VSR
The upgrade to BESSY VSR, which is now being developed, also goes back to a concept in which Godehard Wüstefeld played a leading role. With BESSY VSR, BESSY II will be expanded into a variable pulse length storage ring in which light pulses of varying duration (1.5 picoseconds or 15 picoseconds) will be generated. This allows users to select the optimum pulse duration for their particular experiment. The concept for a variable pulse length storage ring is one of the world's most outstanding further developments of modern synchrotron radiation sources.
Horst Klein Research Prize
The prize was awarded on 21 March 2019 at the Spring Conference (Matter and Cosmos Section) of the Deutsche Physikalische Gesellschaft in Munich by the Physikalischer Verein Frankfurt, the Department of Physics of the Goethe University Frankfurt and the Arbeitskreis Beschleunigerphysik (AKBP) of the Deutsche Physikalische Gesellschaft. The Horst Klein Research Prize is aimed at internationally renowned scientists from Germany and abroad who have distinguished themselves through outstanding achievements of great significance and originality. The prize, which is intended to commemorate the accelerator physicist Horst Klein, is endowed with 5,000 euros and is awarded by the Goethe University Frankfurt, the Fückstiftung, Professors Schempp and Schmidt-Böcking and Pfeiffer Vacuum.
red.
https://www.helmholtz-berlin.de/pubbin/news_seite?nid=20420;sprache=en
- Copy link
-
Magnetic imaging: Micro-flowers increase the local magnetic field
Materials with magnetic nanostructures have many potential applications such as in spintronics. To explore such materials, nanoscale magnetic-sensitive imaging techniques are very useful, but up to now only weak magnetic fields could be applied during the imaging process. Now an international collaboration led by Dr. Sergio Valencia, HZB, has developed an approach that overcomes this limitation. The team designed tiny magnetic flux concentrators (MFCs), into which the sample is placed. The geometry of the MFCs resembles a flower with a number of petals which focus the applied magnetic field into its center. This greatly expands the magnetic field range available during imaging, and so the range of magnetic systems that can be investigated. The micro-flowers, enhancing magnetic fields locally, can find application in different nanometric magnetic microscopy techniques.
-
Disorder creates new properties in compound semiconductors
An international research team has demonstrated that the intrinsic disorder of the compound semiconductor CuInSnS₄ can be exploited to influence its optical properties. While the atomic vibrations also sense the local disorder, their response is averaged over many different local environments and therefore appear isotropic, as expected for a cubic crystal. In contrast, the optical excitations, known as excitons, are much more sensitive to the local arrangement of atoms. Surprisingly, they show a direction-dependent optical response even though the average crystal structure is cubic. These findings shed new light on the relationship between disorder and material properties, opening up new options for targeted 'disorder engineering' in optoelectronic and photocatalytic devices.
-
Superconducting TES array X-ray spectrometer goes into operation at BESSY II
Europe's first and only TES-spectrometer at a synchrotron source is now in operation at BESSY II, developed within a collaboration between the HZB, the MPI-CEC (Mühlheim-an-der-Ruhr, Germany) and the NIST (Boulder CO, USA). The photon detection efficiency of the new instrument exceeds that of wavelength-dispersive X-ray emission spectrometers by a factor of 100 to 1000. It will be used to investigate the electronic properties of atomically thin layers, nanostructures and highly diluted atomic and molecular samples. The team is looking forward to receiving exciting research proposals from the user community.