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@ARTICLE{Mller:166165,
      author       = {Müller, L. and Schleitzer, S. and Gutt, C. and Pfau, B.
                      and Schaffert, S. and Geilhufe, J. and von Korff Schmising,
                      C. and Schneider, M. and Günther, C. M. and Büttner, F.
                      and Capotondi, F. and Pedersoli, E. and Düsterer, S. and
                      Redlin, H. and Al-Shemmary, A. and Treusch, R. and Bach, J.
                      and Frömter, R. and Vodungbo, B. and Gautier, J. and
                      Zeitoun, P. and Popescu, H. and Lopez-Flores, V. and
                      Beaulieu, N. and Sirotti, F. and Jaouen, N. and Malinowski,
                      G. and Tudu, B. and Li, K. and Lüning, J. and Oepen, H. P.
                      and Kiskinova, M. and Eisebitt, S. and Grübel, G.},
      title        = {{U}ltrafast {D}ynamics of {M}agnetic {D}omain {S}tructures
                      {P}robed by {C}oherent {F}ree-{E}lectron {L}aser {L}ight},
      journal      = {Synchrotron radiation news},
      volume       = {26},
      number       = {6},
      issn         = {1931-7344},
      address      = {Philadelphia, Pa.},
      publisher    = {Taylor $\&$ Francis},
      reportid     = {DESY-2014-01095},
      pages        = {27 - 32},
      year         = {2013},
      abstract     = {The free-electron laser (FEL) sources FLASH in Hamburg,
                      LCLS at Stanford, and FERMI in Trieste provide XUV to soft
                      X-ray radiation (FLASH and FERMI) or soft to hard X-ray
                      radiation (LCLS) with unprecedented parameters in terms of
                      ultrashort pulse length, high photon flux, and coherence.
                      These properties make FELs ideal tools for studying
                      ultrafast dynamics in matter on a previously unaccessible
                      level. This paper first reviews results obtained at FEL
                      sources during the last few years in the field of magnetism
                      research. We start with pioneering experiments at FLASH
                      demonstrating the feasibility of magnetic scattering at FELs
                      [1, 2], then present pump–probe scattering experiments [3,
                      4] as well as the first FEL magnetic imaging experiments
                      [5], and finally discuss a limitation of the scattering
                      methods due to a quenching of the magnetic scattering signal
                      by high-fluence FEL pulses [6]. All of the presented
                      experiments exploit the X-ray magnetic circular dichroism
                      effect [7, 8] to obtain element-specific magnetic scattering
                      contrast, as known from synchrotron experiments [9–12].},
      cin          = {FS-CXS / DOOR / FS-FL / FS-LA},
      ddc          = {530},
      cid          = {I:(DE-H253)FS-CXS-20130727 / I:(DE-H253)HAS-User-20120731 /
                      I:(DE-H253)FS-FL-20120731 / I:(DE-H253)FS-LA-20130416},
      pnm          = {FLASH Beamline BL1 (POF2-54G16) / FLASH Beamline BL2
                      (POF2-54G16) / FLASH Beamline BL3 (POF2-54G16)},
      pid          = {G:(DE-H253)POF2-BL1-20130405 / G:(DE-H253)POF2-BL2-20130405
                      / G:(DE-H253)POF2-BL3-20130405},
      experiment   = {EXP:(DE-H253)F-BL2-20150101 / EXP:(DE-H253)F-BL3-20150101},
      typ          = {PUB:(DE-HGF)16},
      UT           = {WOS:00},
      doi          = {10.1080/08940886.2013.850384},
      url          = {https://bib-pubdb1.desy.de/record/166165},
}