- 1.1 Accelerator-based light sources
- 1.2 Free-electron lasers
- 1.3 Historical development of the XFEL
- References
- 2.1 Historical background
-
2.2 TTF FEL, Phase 1.
- 2.2.1 Accelerator R&D
- 2.2.2 FEL research.
- 2.2.3 Results.
- 2.2.4 Experience from commissioning procedures
- 2.3 TTF FEL, Phase 2 – FLASH
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2.3.1 Design
- 2.3.2 Installation.
- 2.3.3 Accelerator commissioning
- 2.3.4 FEL commissioning
- 2.3.5 Experience form the first user operation periods
- 2.3.6 Next steps for FLASH
- References.
- 3.1 Introduction.
- 3.2 Injector
- 3.3 Linear accelerator
- 3.4 Beam distribution system
- 3.5 Undulators
- 3.6 Photon beamlines
- 3.7 Experimental stations
- 3.8 Schenefeld campus
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4.1 Overview
- 4.1.1 Introduction
- 4.1.2 Overall layout and choice of parameters.
- 4.1.3 Operational flexibility and future options
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4.2 Linac.
- 4.2.1 Cavities
- 4.2.2 Auxiliaries
- 4.2.3 Vacuum system
- 4.2.4 High power RF system.
- 4.2.5 Low level radio frequency control
-
4.3 Injector
- 4.3.1 General layout
- 4.3.2 Experimental status and future developments
- 4.3.3 Photocathode laser
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4.4 The bunch compressor system and start-to-end simulations
- 4.4.1 Introduction and layout
- 4.4.2 Space charge and coherent synchrotron radiation effects
- 4.4.3 RF set-up and tolerances.
- 4.4.4 Instabilities driven by space charge and coherent synchrotron radiation
- 4.4.5 Start-to-end simulation
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4.5 Beam optics and dynamics
- 4.5.1 Main linac
- 4.5.2 Post-linac collimation
- 4.5.3 Beam distribution and undulators
- 4.5.4 Transverse beam stabilisation
-
4.6 Beam diagnostics
- 4.6.1 Requirements.
- 4.6.2 Measurements of projected bunch properties
- 4.6.3 Measurement of slice properties
-
4.7 Technical layout.
- 4.7.1 Warm vacuum system.
- 4.7.2 Magnets.
- 4.7.3 Kickers.
- 4.7.4 Beam dumps
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4.8 Synchronisation system for the XFEL
- 4.8.1 Introduction
- 4.8.2 Layout of the XFEL synchronisation system.
- 4.8.3 Distribution of trigger and clock signals
- 4.8.4 Synchronisation of the LLRF for the main linac
-
4.9 Summary of costs and manpower
- 4.9.1 Costs and manpower requirements of the superconducting linac
- References
-
5.1 Overview
- 5.1.1 Principles of XFEL operation
- 5.1.2 Design criteria for the European XFEL
-
5.2 FEL radiation parameters
- 5.2.1 Defining undulator parameters.
- 5.2.2 Radiation parameters of SASE 3
- 5.2.3 Statistical properties of the radiation
- 5.2.4 Higher harmonics
-
5.3 Spontaneous synchrotron radiation
- 5.3.1 Undulator parameters
- 5.3.2 Spontaneous radiation parameters
-
5.4 Undulators systems
- 5.4.1 Choice of undulator parameters
- 5.4.2 Basic tolerance requirements.
- 5.4.3 Undulator segments
- 5.4.4 Intersections
- 5.4.5 Other components.
- 5.4.6 Implementation of undulator systems
- 5.4.7 Summary
-
5.5 Photon diagnostics of FEL radiation
- 5.5.1 Trajectory alignment
- 5.5.2 Gap adjustment
- 5.5.3 Phase tuning
- 5.5.4 Hardware setup
- 5.5.5 Test at PETRA II
- 5.6 Future extensions to the European XFEL Facility
- 5.7 Summary of costs and manpower requirements
- References
- 6.1 Overview of the X-ray systems
-
6.2 Photon beam transport
- 6.2.1 Photon beamline concept
- 6.2.2 X-ray optical elements
- 6.2.3 Other beam transport elements
- 6.2.4 Description of the beamlines
-
6.3 Photon beam diagnostics
- 6.3.1 Characterisation of beam properties
- 6.3.2 Online diagnostics
-
6.4 Scientific instruments
- 6.4.1 Small Quantum Systems
- 6.4.2 High Energy Density matter experiments
- 6.4.3 Coherent X-ray scattering and lensless imaging in materials science
- 6.4.4 X-ray Photon Correlation Spectroscopy
- 6.4.5 X-ray absorption spectroscopy
- 6.4.6 Femtosecond diffraction experiments
- 6.4.7 Ultra-fast coherent diffraction imaging of single particles, clusters and biomolecules
- 6.4.8 Research and development on x-ray instrumentation
-
6.5 Specific XFEL experiments instrumentation
- 6.5.1 Sample environment and manipulation.
- 6.5.2 X-ray optics
- 6.5.3 Optical lasers
- 6.5.4 Detectors and requirements
- 6.6 Summary of cost and manpower requirements
- References
-
7.1 Site layout and civil construction
- 7.1.1 Overall site layout.
- 7.1.2 Civil construction.
-
7.2 Conventional technical infrastructure
- 7.2.1 Power distribution and power supplies
- 7.2.2 Magnet power supplies.
- 7.2.3 Magnet water cooling and air conditioning
- 7.2.4 Heating, ventilation and air conditioning
- 7.2.5 Cryogenics
- 7.2.6 Accelerator Module Test Facility
- 7.2.7 Survey and alignment of XFEL
- 7.2.8 Installation of components
-
7.3 Controls and operation.
- 7.3.1 Control systems
- 7.3.2 Radiation safety
- 7.3.3 General safety
- 7.3.4 Personnel interlock
- 7.4 Summary of costs and manpower requirements
- References.
- 8.1 General considerations.
- 8.2 Transition phase.
- 8.3 User operation
- 8.4 Operation budget
- 9.1 Introduction.
-
9.2 Internal organisation of the XFEL GmbH
- 9.2.1 General aspects
- 9.2.2 Primary tasks and internal structure of the XFEL GmbH
- 9.2.3 Operation of the accelerator complex
- 9.2.4 Build-up of the XFEL staff complement
- 9.2.5 Status of personnel and recruitment policy.
-
9.3 General project structure and procedures for the construction period
- 9.3.1 Principles
- 9.3.2 Collaboration agreements between contributing institutes and XFEL GmbH
- 9.3.3 Project management structure and oversight.
- 9.3.4 Later operation of the equipment contributed in kind.
-
9.4 Special relationship between the XFEL GmbH and DESY
- 9.4.1 DESY as contributor to the construction, commissioning and operation of the XFEL facility.
- 9.4.2 DESY as host for the XFEL GmbH
-
9.5 Project management
- 9.5.1 Overview
- 9.5.2 Roles and responsibilities within the XFEL project
- 9.5.3 Project management tools
- References
- 10.1 Total project cost
- 10.2 Risk analysis.
- 10.3 Operation cost.
- 10.4 Time schedule.
- 10.5 Budget profile.
- References
