O. Hensler scite author profile

Extreme-ultraviolet to x-ray free-electron lasers (FELs) in operation for scientific applications are up to now single-user facilities. While most FELs generate around 100 photon pulses per second, FLASH at DESY can deliver almost two orders of magnitude more pulses in this time span due to its superconducting accelerator technology. This makes the facility a prime candidate to realize the next step in FELs-dividing the electron pulse trains into several FEL lines and delivering photon pulses to several users at the same time. Hence, FLASH has been extended with a second undulator line and self-amplified spontaneous emission (SASE) is demonstrated in both FELs simultaneously. FLASH can now deliver MHz pulse trains to two user experiments in parallel with individually selected photon beam characteristics. First results of the capabilities of this extension are shown with emphasis on independent variation of wavelength, repetition rate, and photon pulse length.

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The FLASH Facility: Advanced Options for FLASH2 and Future Perspectives

Faatz

Braune

Hensler

et al. 2017

Applied Sciences

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Since 2016, the two free-electron laser (FEL) lines FLASH1 and FLASH2 have been run simultaneously for users at DESY in Hamburg. With the installation of variable gap undulators in the new FLASH2 FEL line, many new possibilities have opened up in terms of photon parameters for experiments. What has been tested so far is post-saturation tapering, reverse tapering, harmonic lasing, harmonic lasing self-seeding and two-color lasing. At the moment, we are working on concepts to enhance the capabilities of the FLASH facility even further. A major part of the upgrade plans, known as FLASH2020, will involve the exchange of the fixed gap undulators in FLASH1 and the implementation of a new flexible undulator scheme aimed at providing coherent radiation for multi-color experiments over a broad wavelength range. The recent achievements in FLASH2 and the current status of plans for the further development of the facility are presented.

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High precision superconducting cavity diagnostics with higher order mode measurements

Molloy

Frisch

McCormick

et al. 2006

Phys. Rev. ST Accel. Beams

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Experiments at the FLASH facility at DESY have demonstrated that the higher order modes induced in superconducting cavities can be used to provide a variety of beam and cavity diagnostics. The axes of the modes can be determined from the beam orbit that produces minimum power in the dipole HOM modes. The phase and amplitude of the dipole modes can be used to obtain high resolution beam position information, and the phase of the monopole modes to measure the beam phase relative to the accelerator rf. For most superconducting accelerators, the existing higher order mode couplers provide the necessary signals, and the downmix and digitizing electronics are straightforward, similar to those for a conventional beam position monitor.

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XFEL: The European X-Ray Free-Electron Laser - Technical Design Report

Abela¹,

Witte²,

Schwarz³

et al. 2006

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O. Hensler

A MHz-repetition-rate hard X-ray free-electron laser driven by a superconducting linear accelerator

Simultaneous operation of two soft x-ray free-electron lasers driven by one linear accelerator

The FLASH Facility: Advanced Options for FLASH2 and Future Perspectives

High precision superconducting cavity diagnostics with higher order mode measurements

XFEL: The European X-Ray Free-Electron Laser - Technical Design Report

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