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@ARTICLE{Wegert:364991,
      author       = {Wegert, Leonard Maximilian and Rauch, Constantin and
                      Schreiner, Stephan and Schneider, Markus and Michel, Thilo
                      and Anton, Gisela and Albertazzi, Bruno and Koenig, Michel
                      and Meyer, Pascal and Fröjdh, Erik and Mozzanica, Aldo and
                      Yang, Yang and Hornung, Johannes and Zielbauer, Bernhard and
                      Martynenko, Artem S. and LePape, Sébastien and Funk, Stefan
                      and Neumayer, Paul},
      title        = {{P}robing ultrafast foam homogenization with grating-based
                      {X}-ray dark-field imaging},
      journal      = {Scientific reports},
      volume       = {15},
      number       = {1},
      issn         = {2045-2322},
      address      = {[London]},
      publisher    = {Springer Nature},
      reportid     = {GSI-2026-00344},
      pages        = {42564},
      year         = {2025},
      note         = {This article is licensed under a Creative Commons
                      Attribution 4.0 International License},
      abstract     = {Microstructured foams are emerging as a promising class of
                      targets, with applications ranging from laser-driven
                      particle acceleration to inertial confinement fusion. To
                      unlock their full potential, a deeper understanding of their
                      properties, especially the changes and behavior of the
                      microstructure under extreme conditions, is required. While
                      recently advancing 3D printed foam targets can be observed
                      by X-ray radiography, the microstructure in chemically
                      produced targets is far below the spatial resolution of
                      conventional radiography. To overcome this limitation, we
                      apply grating-based X-ray dark-field imaging to observe
                      structural changes in foams that are rapidly heated by
                      laser-accelerated proton pulses. The experimental data is
                      compared to synthetic dark-field values obtained from
                      hydrodynamic simulations of a simplified foam model. Both
                      experimental and simulation results demonstrate the
                      viability of utilizing grating-based dark-field imaging for
                      observing microstructural changes in foam targets.},
      cin          = {PPH},
      ddc          = {600},
      cid          = {I:(DE-Ds200)PPH-20051214OR027},
      pnm          = {612 - Cosmic Matter in the Laboratory (POF4-612) / DFG
                      project G:(GEPRIS)452935060 - Einzelschuss
                      Röntgen-Phasenkonstrast Abbildung von dichten Plasmen
                      (452935060) / FAIR Phase-0 - FAIR Phase-0 Research Program
                      (GSI-FAIR-Phase-0) / DFG project G:(GEPRIS)491382106 -
                      Open-Access-Publikationskosten / 2025-2027 / GSI
                      Helmholtzzentrum für Schwerionenforschung (491382106)},
      pid          = {G:(DE-HGF)POF4-612 / G:(GEPRIS)452935060 /
                      G:(Ds200)GSI-FAIR-Phase-0 / G:(GEPRIS)491382106},
      experiment   = {$EXP:(DE-Ds200)Experiment_without_proposal_number-20200803$},
      typ          = {PUB:(DE-HGF)16},
      pubmed       = {pmid:41298900},
      UT           = {WOS:001629328000006},
      doi          = {10.1038/s41598-025-30010-8},
      url          = {https://repository.gsi.de/record/364991},
}