Jitter-correction for IR/UV-XUV pump-probe experiments at the FLASH free-electron laser

Savelyev, Evgeny; Boll, Rebecca; Bomme, Cédric; Schirmel, Nora; Redlin, H.; Erk, Benjamin; Düsterer, S.; Müller, Erland; Höppner, Hauke; Toleikis, S.; Müller, Jost; Czwalinna, Marie Kristin; Treusch, R.; Kierspel, Thomas; Mullins, Terry; Trippel, Sebastian; Wiese, Joss; Küpper, Jochen; Brauße, Felix; Krecinic, Faruk; Rouzée, Arnaud; Rudawski, Piotr; Johnsson, Per; Amini, Kasra; Lauer, Alexandra; Burt, Michael; Brouard, M.; Christensen, Lars Rune; Thøgersen, Jan; Stapelfeldt, Henrik; Berrah, N.; Müller, M.; Ulmer, Anatoli; Techert, Simone; Rudenko, Artem; Rolles, Daniel

doi:10.1088/1367-2630/aa652d

Cited by 38 publications

(52 citation statements)

References 87 publications

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“…for most of the settings investigated so far. This result tells us that one can indeed significantly improve the time resolution of optical-XUV pump-probe experiments by sorting the acquired data according to the electron bunch arrival times measured by the BAM (Savelyev et al, 2017). Moreover, this diagnostic can in future be used to characterize and improve the performance of the FLASH FEL synchronization system and the arrival time detector.…”

Section: Resultsmentioning

confidence: 82%

FLASH free-electron laser single-shot temporal diagnostic: terahertz-field-driven streaking

et al. 2018

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The commissioning of a terahertz-field-driven streak camera installed at the free-electron laser (FEL) FLASH at DESY in Hamburg, being able to deliver photon pulse duration as well as arrival time information with $ 10 fs resolution for each single XUV FEL pulse, is reported. Pulse durations between 300 fs and <15 fs have been measured for different FLASH FEL settings. A comparison between the XUV pulse arrival time and the FEL electron bunch arrival time measured at the FLASH linac section exhibits a correlation width of 20 fs r.m.s., thus demonstrating the excellent operation stability of FLASH. In addition, the terahertz-streaking setup was operated simultaneously to an alternative method to determine the FEL pulse duration based on spectral analysis. FLASH pulse duration derived from simple spectral analysis is in good agreement with that from terahertz-streaking measurement.

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Section: Resultsmentioning

confidence: 82%

FLASH free-electron laser single-shot temporal diagnostic: terahertz-field-driven streaking

et al. 2018

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“…Both the FLASH FEL as well as the pumpprobe laser operated at a repetition rate of 10 Hz. From a measurement of the electron bunch duration in the FLASH accelerator (Dü sterer et al, 2014;Savelyev et al, 2017), the XUV pulse length was estimated to be 120 fs (FWHM), while Sketch of the experimental setup showing the molecular beam, the path of the UV, NIR and XUV laser beams, and the double-sided velocity-map imaging spectrometer. Ions were detected with an MCP and a fast P47 phosphor screen detector coupled with TimepixCam.…”

Section: Methodsmentioning

confidence: 99%

“…Electron images, which are discussed in a separate publication (Brauße et al, 2018), were recorded at 10 Hz using a commercial CCD camera (Allied Vision Pike F-145B), while the ion images were recorded with TimepixCam, which is described in detail in the following section. Further details on the data analysis and sorting procedure for pump-probe experiments using the FLASH FEL in combination with the FLASH pump-probe laser, such as the normalization of the data to the fluctuating XUV pulse energy and the correction for the arrival-time jitter between the XUV and the UV/NIR pulses, are given by Savelyev et al (2017).…”

Section: Methodsmentioning

confidence: 99%

“…The current version of TimepixCam, which employs the UNO readout system for the data acquisition (Imatek, 2016), allows a continuous readout at approximately 10 Hz, limited by the USB connection to the computer and the camera software. The FLASH 'bunch ID', which is an identification number for each FEL pulse, was stored along with the data from each readout cycle and was used to establish the correspondence of the TimepixCam frames and the FLASH bunches so that various intensity and pump-probe timing corrections could be applied (Savelyev et al, 2017). This association was made by the readout software, which recorded the bunch ID in the header of each camera frame.…”

Section: Timepixcammentioning

confidence: 99%

“…The increased availability of short-pulse extreme ultraviolet (XUV) and (soft) X-ray sources such as free-electron lasers (FELs) (Ackermann et al, 2007;Shintake et al, 2008;Feldhaus, 2010;Emma et al, 2010;Allaria et al, 2012Allaria et al, , 2013Ishikawa et al, 2012;Ullrich et al, 2012) and high-order harmonic generation (HHG) sources (Popmintchev et al, 2010;Chini et al, 2014;Hä drich et al, 2014), accompanied by continuing advances in femtosecond laser technology, promises a new era for femtosecond pump-probe experiments studying the dynamics of photochemical reactions in gas-phase molecules. Many of these experiments are performed using the velocitymap imaging (VMI) technique (Eppink & Parker, 1997), where the photoelectrons or fragment ions that are created by the ionizing light pulse are accelerated by an electric field and projected onto phosphor screen detectors that are commonly read out by CCD or CMOS cameras.…”

Section: Introductionmentioning

confidence: 99%

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Time-resolved ion imaging at free-electron lasers using TimepixCam

Fisher-Levine

Boll

Ziaee

et al. 2018

J Synchrotron Radiat

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The application of a novel fast optical-imaging camera, TimepixCam, to molecular photoionization experiments using the velocity-map imaging technique at a free-electron laser is described. TimepixCam is a 256 × 256 pixel CMOS camera that is able to detect and time-stamp ion hits with 20 ns timing resolution, thus making it possible to record ion momentum images for all fragment ions simultaneously and avoiding the need to gate the detector on a single fragment. This allows the recording of significantly more data within a given amount of beam time and is particularly useful for pump-probe experiments, where drifts, for example, in the timing and pulse energy of the free-electron laser, severely limit the comparability of pump-probe scans for different fragments taken consecutively. In principle, this also allows ion-ion covariance or coincidence techniques to be applied to determine angular correlations between fragments.

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Development of Ultrafast X-ray Free Electron Laser Tools in (Bio)Chemical Research

Techert

Veedu

Bari

2020

Topics in Applied Physics

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The chapter will focus on fundamental aspects and methodological challenges of X-ray free electron laser research and recent developments in the related field of ultrafast X-ray science. Selected examples proving “molecular movie capabilities” of Free-electron laser radiation investigating gas phase chemistry, chemistry in liquids and transformations in the solid state will be introduced. They will be discussed in the context of ultrafast X-ray studies of complex biochemical research, and time-resolved X-ray characterisation of energy storage materials and energy bionics.

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Jitter-correction for IR/UV-XUV pump-probe experiments at the FLASH free-electron laser

Cited by 38 publications

References 87 publications

FLASH free-electron laser single-shot temporal diagnostic: terahertz-field-driven streaking

FLASH free-electron laser single-shot temporal diagnostic: terahertz-field-driven streaking

Time-resolved ion imaging at free-electron lasers using TimepixCam

Development of Ultrafast X-ray Free Electron Laser Tools in (Bio)Chemical Research

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