Synchrotron Light Sources and Free-Electron Lasers Accelerator Physics, Instrumentation and Science Applications

Synchrotron Radiation Physics.- 

Ultrashort Pulses from Synchrotron Radiation Sources.- 

Accelerator-Based THz Radiation Sources.- 

Seeding and Harmonic Generation in Free-Electron Lasers.- 

High-Gain Free-Electron Laser Theory, Introduction.- 

Self-Seeded Free-Electron Lasers.- 

Echo-Enabled Harmonic Generation.- 

Brilliant Light Sources driven by Laser-Plasma Accelerators.- 

Storage Ring Design for Synchrotron Radiation Sources.- 

FLASH: The First Superconducting X-Ray Free-Electron Laser.- 

The Linac Coherent Light Source: Concept Development and Design Considerations.- 

The SACLA X-Ray Free-Electron Laser Based on Normal-Conducting C-Band Technology.- 

Energy-Recovery Linacs.- 

Integrated Multimagnet Systems.- 

Superconducting RF: Enabling Technology for Modern Light Sources.- 

Superconducting Radio-Frequency for High-Current CW Applications.- 

High Brightness Photo Injectors for Brilliant Light Sources.- 

Vacuum Systems for Synchrotron Light Sources and FELs.- 

Coupled-Bunch Instabilities in Storage Rings and Feedback Systems.- 

Control Systems for Accelerators: Operational Tools.- 

SRLS Beam Instrumentation and Diagnostics.- 

Free-Electron Laser Beam Instrumentation and Diagnostics.- 

Synchronization of FEL Components with Fiber Laser Techniques.- 

Shaping Photon Beams with Undulators and Wigglers.- 

Superconducting Wigglers and Undulators.- 

Coherence Properties of Third-Generation Synchrotron Sources and Free-Electron Lasers.- 

Characterization of the Time Structure of Free-Electron Laser Radiation.- 

Split-and-Delay Units for Soft and Hard X-Rays.- 

Focusing Mirror for Coherent Hard X-Rays.- 

Perfect Crystal Optics.- 

Sub-micrometer Focusing and High-Resolution Imaging with Refractive Lenses and Multilayer Laue Optics.-  

Hybrid Pixel Photon Counting X-Ray Detectors for Synchrotron Radiation.- 

Integrating Hybrid Area Detectors for Storage Ring and Free-Electron Laser Applications.- 

High Speed Imaging and Spectroscopy with Low Energy X-Rays.- 

X-Ray Holography.- 

Imaging of Objects by Coherent Diffraction of X-Ray Free-Electron Laser Pulses.- 

Quantum and Nonlinear Optics with Hard X-Rays.- 

Interaction of Intense X-Ray Beams with Atoms.- 

Molecular Soft X-Ray Emission Spectroscopy.- 

Molecular Physics and Gas-Phase Chemistry with Free-Electron Lasers.- 

Clusters and Nanocrystals.- 

Metrology with Synchrotron Radiation.- 

Putting Molecules in the Picture: Using Correlated Light Microscopy and Soft X-Ray Tomography to Study Cells.- 

Synchrotron Small-Angle X-Ray Scattering on Biological Macromolecules in Solution.- 

Structural Biology Applications of Synchrotron Radiation and X-Ray Free-Electron Lasers.- 

Application of Micro- and Nanobeams for Materials Science.- 

High-Energy X-Ray Scattering and Imaging.- 

Engineering Materials Science Using Synchrotron Radiation.- 

X-Ray Studies of Energy Materials.- 

Applications of the X-Ray Standing Wave Technique in Physical Science Research.- 

Synchrotron and FEL Studies of Matter at High Pressures.- 

Synchrotron X-Ray Scattering from Liquid Surfaces and Interfaces.- 

X-Ray Studies of Water.- 

Structural Dynamics of Materials Probed by X-Ray Photon Correlation Spectroscopy.- 

Angle-Resolved Photoemission.- 

IR spectroscopy and spectro-microscopy with synchrotron radiation.- 

The X-Ray View of Ultrafast Magnetism.- 

High-Resolution Inelastic X-Ray Scattering I: Context, Spectrometers, Samples, and Superconductors.- 

High-Resolution Inelastic X-Ray Scattering Part II: Scattering Theory, Harmonic Phonons, and Calculations.- 

Nuclear Resonance.- 

High Resolution Resonant Inelastic X-Ray Scattering from Solids in the Soft Range.- 

Resonant Inelastic X-ray Scattering (RIXS) Studies in Chemistry: Present and Future.- 

High-Resolution Soft X-ray Resonant Inelastic X-ray Scattering.- 

Chemical Mapping of Ancient Artifacts and Fossils with X-Ray Spectroscopy.- 

Using Synchrotron Radiation for Characterization of Cultural Heritage Materials

Eberhard J. Jaeschke studied Physics at the universities of Erlangen and Princeton. After his Ph.D. in Nuclear Physics, he moved to the Max-Planck-Institut für Kernphysik, Heidelberg, where his interests turned more and more to the physics of accelerators and their development. At Heidelberg University, he taught experimental physics, got his habilitation, and was promoted to professor (apl). The Heidelberg-TSR – the first heavy ion cooler ring with electron and laser cooling, which he managed as project leader – was a worldwide recognized success. From Heidelberg, Eberhard Jaeschke moved to Berlin, becoming member of the board of directors of the Berliner-Elektronenspeicherring-Gesellschaft für Synchrotronstrahlung (BESSY), and received a call for a full professorship at the Humboldt Universität. He was project director of the construction of BESSY II, the first German third-generation synchrotron light source. His marvelous team managed to build BESSY II in time and on budget and turned after this success to the design of modern light sources, the free-electron lasers (FELs).

Research stays over the years were at Los Alamos, Stony Brook, Tokyo, Chalk River, and Novosibirsk, at the Budker Institute of Nuclear Physics.

Eberhard Jaeschke retired from BESSY after 18 years on the board and is now professor emeritus. In 2010, he was awarded the Officer’s Cross of the Order of Merit of the Federal Republic of Germany.

Shaukat Khan Shaukat Khan studied Physics at Heidelberg University and received his doctor’s degree in 1987 for work in nuclear spectroscopy at the Max Planck Institute for Nuclear Physics. While working as a postdoc on a silicon vertex detector for the ARGUS experiment at DESY/Hamburg, he became more and more interested in accelerator physics. Consequently, he joined the BESSY II project in Berlin in 1993 where his research interests included collective beam instabilities and the generation of ultrashort X-ray pulses. After receiving his lecturer qualification (habilitation) from the Humboldt University of Berlin, he became W2 professor at Hamburg University in 2006 and full professor at TU Dortmund University in 2008. In addition to holding a chair in accelerator physics, he is director at the university-based synchrotron radiation facility DELTA where his working group develops laser-seeding techniques to produce ultrashort radiation pulses.

Jochen R. Schneider studied Physics at the University of Hamburg and did his Ph.D. under the guidance of H. Maier-Leibnitz at the Institute Max von Laue-Paul Langevin in Grenoble, France. After working at the Hahn-Meitner Institute and the Technical University in Berlin, in December 1989 he moved to the Deutsches Elektronen-Synchrotron DESY in Hamburg, Germany. His main interest is in structural phase transitions and electronic properties of solids, as well as synchrotron radiation instrumentation. He developed ? -ray diffractometry and pioneered the application of high-energy synchrotron radiation in condensed matter research. In 1993 he became head of the synchrotron radiation laboratory HASYLAB at DESY; from 2000 to 2007, he was the first DESY Photon Science research director. In his tenure he initiated DESY’s third generation synchrotron radiation facility PETRA III, the free-electron lasers FLASH and European XFEL, and the Center for Free-Electron Laser Science (CFEL). After 2 years at SLAC National Accelerator Laboratory at Stanford in charge of the experimental facilities division of the Linac Coherent Light Source (LCLS), he is now a fellow of CFEL and scientific advisor to the DESY Photon Science management.

In 1981 Jochen Schneider received the Victor Moritz Goldschmidt Award of the German Mineralogical Society, in 2001 the European Crystallography Prize, and in 2008 the Officer’s Cross of the Order of Merit of the Federal Republic of Germany.

Jerome B. Hastings Jerome Hastings studied Applied Physics at Cornell University and did his Ph.D. under the guidance of B. W. Batterman. After working at the National Synchrotron Light Source for nearly 25 years, in October 2001 he moved to the SLAC National Accelerator Laboratory in Menlo Park, CA, USA. His main interest is in methods and instrumentation for accelerator based light sources. He developed the applications of ultrahigh-energy resolution methods applied to synchrotron-based Mössbauer spectroscopy and inelastic X-ray scattering. In addition, he led the ultrashort pulse spontaneous radiation facility “Sub-Picosecond Pulse Source” at the SLAC National Accelerator Laboratory from 2001 to 2006. In his tenure at the National Synchrotron Light Source (NSLS), the R&D effort developed many of the methods and instruments in common use today at third-generation synchrotron light sources. He is the science advisor for the LCLS and professor (research) in the Photon Science Faculty at the SLAC National Accelerator Laboratory. He