Daniel Treyer scite author profile

The SwissFEL X-ray Free Electron Laser (XFEL) facility started construction at the Paul Scherrer Institute (Villigen, Switzerland) in 2013 and will be ready to accept its first users in 2018 on the Aramis hard X-ray branch. In the following sections we will summarize the various aspects of the project, including the design of the soft and hard X-ray branches of the accelerator, the results of SwissFEL performance simulations, details of the photon beamlines and experimental stations, and our first commissioning results.

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A compact and cost-effective hard X-ray free-electron laser driven by a high-brightness and low-energy electron beam

Prat

et al. 2020

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Commissioning experience and beam physics measurements at the SwissFEL Injector Test Facility

Schietinger¹,

Hauff²,

Pal³

et al. 2016

Phys. Rev. Accel. Beams

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The SwissFEL Injector Test Facility operated at the Paul Scherrer Institute between 2010 and 2014, serving as a pilot plant and testbed for the development and realization of SwissFEL, the X-ray Free-Electron Laser facility under construction at the same institute. The test facility consisted of a laser-driven rf electron gun followed by an S-band booster linac, a magnetic bunch compression chicane and a diagnostic section including a transverse deflecting rf cavity. It delivered electron bunches of up to 200 pC charge and up to 250 MeV beam energy at a repetition rate of 10 Hz. The measurements performed at the test facility not only demonstrated the beam parameters required to drive the first stage of an FEL facility, but also led to significant advances in instrumentation technologies, beam characterization methods and the generation, transport and compression of ultra-low-emittance beams. We give a comprehensive overview of the commissioning experience of the principal subsystems and the beam physics measurements performed during the operation of the test facility, including the results of the test of an in-vacuum undulator prototype generating radiation in the vacuum ultraviolet and optical range.

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Ultra-broadband infrared pump-probe spectroscopy using synchrotron radiation and a tuneable pump

Carroll

Friedli

Lerch

et al. 2011

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Synchrotron infrared sources have become popular mainly because of their excellent broadband brilliance, which enables spectroscopically resolved spatial-mapping of stationary objects at the diffraction limit. In this article we focus on an often-neglected further advantage of such sources - their unique time-structure - to bring such broadband spectroscopy to the time domain, for studying dynamic phenomenon down to the 100 ps limit. We describe the ultra-broadband (12.5 to 1.1 μm) Fourier transform pump-probe setup, for condensed matter transmission- and reflection-spectroscopy, installed at the X01DC infrared beam-line of the Swiss Light Source (SLS). The optical pump consists of a widely tuneable 100 ps 1 kHz laser system, covering 94% of the 16 to 1.1 μm range. A thorough description of the system is given, including (i) the vector-modulator providing purely electronic tuning of the pump-probe overlap up to 1 ms with sub-ps time resolution, (ii) the 500 MHz data acquisition system interfaced with the experimental physics and industrial control system (EPICS) based SLS control system for consecutive pulse sampling, and (iii) the step-scan time-slice Fourier transform scheme for simultaneous recording of the dual-channel pumped, un-pumped, and difference spectra. The typical signal/noise ratio of a single interferogram in a 100 ps time slice is 300 (measured during one single 140 s TopUp period). This signal/noise ratio is comparable to that of existing gated Globar pump-probe Fourier transform spectroscopy, but brings up to four orders of magnitude better time resolution. To showcase the utility of broadband pump-probe spectroscopy, we investigate a Ge-on-Si material system similar to that in which optically pumped direct-gap lasing was recently reported. We show that the mid-infrared reflection-spectra can be used to determine the optically injected carrier density, while the mid- and near-infrared transmission-spectra can be used to separate the strong pump-induced absorption and inversion processes present at the direct-gap energy.

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Investigation of a self-calibrating SSB modulator

Treyer

Bächtold

2005

IEEE Trans. Microwave Theory Techn.

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

Decking¹,

Abeghyan²,

Abramian³

et al. 2020

Nat. Photonics

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Condition-based Maintenance: Model vs. Statistics a Performance Comparison

Engeler

Treyer²,

Zogg³

et al. 2016

Procedia CIRP

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Daniel Treyer

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

SwissFEL: The Swiss X-ray Free Electron Laser

A compact and cost-effective hard X-ray free-electron laser driven by a high-brightness and low-energy electron beam

Commissioning experience and beam physics measurements at the SwissFEL Injector Test Facility

Ultra-broadband infrared pump-probe spectroscopy using synchrotron radiation and a tuneable pump

Investigation of a self-calibrating SSB modulator

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

Condition-based Maintenance: Model vs. Statistics a Performance Comparison

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