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SSRL is a National User Facility which provides synchrotron radiation, a name given to electromagnetic radiation in the x-ray, ultraviolet, visible and infrared realms produced by electrons circulating in a storage ring (Stanford Positron Electron Asymmetric Ring - SPEAR) at nearly the speed of light. The extremely bright light that is produced ...
National Synchrotron Radiation Laboratory (NSRL) University of Science and Technology China, Hefei: China: 0.8: 66.13: 1991: Beijing Synchrotron Radiation Facility (BSRF) Institute of High Energy Physics, Chinese Academy of Sciences, Beijing China: 2.5: 1991: European Synchrotron Radiation Facility (ESRF) Grenoble: France: 6: 844: 1992: 2019
Joachim Stöhr (born September 28, 1947) [1] is a physicist and professor emeritus of the Photon Science Department of Stanford University.His research has focused on the development of X-ray and synchrotron radiation techniques and their applications in different scientific fields with emphasis on surface science and magnetism.
The Stanford Synchrotron Radiation Lightsource (SSRL) is a synchrotron light user facility located on the SLAC campus. Originally built for particle physics, it was used in experiments where the J/ψ meson was discovered. It is now used exclusively for materials science and biology experiments which take advantage of the high-intensity ...
SSRL is an acronym that may refer one of two university laboratories in the United States of America: Stanford Synchrotron Radiation Lightsource at Stanford University at an off-campus location in Menlo Park, California; Social Science Research Laboratory at San Diego State University in San Diego, California
NSLS-II is a synchrotron light source, designed to produce X-rays 10,000 times brighter than BNL's original light source, the National Synchrotron Light Source (NSLS). NSLS-II supports research in energy security, advanced materials synthesis and manufacturing, environment, and human health. [4]
Especially when artificially produced, synchrotron radiation is notable for its: High brilliance, many orders of magnitude more than with X-rays produced in conventional X-ray tubes: 3rd-generation sources typically have a brilliance larger than 10 18 photons·s −1 ·mm −2 ·mrad −2 /(0.1%BW), where 0.1%BW denotes a bandwidth 10 −3 ω centered around the frequency ω.
The first wiggler used for generation of synchrotron radiation was a 7 pole wiggler installed in the SSRL in 1979. Since these first insertions the number of undulators and wigglers in synchrotron radiation facilities throughout the world have proliferated and they are one of the driving technologies behind the next generation of light sources ...