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@ARTICLE{LasoGarcia:622084,
      author       = {Laso Garcia, Alejandro and Yang, Long and Bouffetier,
                      Victorien and Appel, Karen and Baehtz, Carsten and Hagemann,
                      Johannes and Höppner, Hauke and Humphries, Oliver and
                      Kluge, Thomas and Mishchenko, Mikhail and Nakatsutsumi,
                      Motoaki and Pelka, Alexander and Preston, Thomas R. and
                      Randolph, Lisa and Zastrau, Ulf and Cowan, Thomas E. and
                      Huang, Lingen and Toncian, Toma},
      title        = {{C}ylindrical compression of thin wires by irradiation with
                      a {J}oule-class short-pulse laser},
      journal      = {Nature Communications},
      volume       = {15},
      number       = {1},
      issn         = {2041-1723},
      address      = {[London]},
      publisher    = {Springer Nature},
      reportid     = {PUBDB-2025-00170},
      pages        = {7896},
      year         = {2024},
      abstract     = {Equation of state measurements at Jovian or stellar
                      conditions are currently conducted by dynamic shock
                      compression driven by multi-kilojoule multi-beam
                      nanosecond-duration lasers. These experiments require
                      precise design of the target and specific tailoring of the
                      spatial and temporal laser profiles to reach the highest
                      pressures. At the same time, the studies are limited by the
                      low repetition rate of the lasers. Here, we show that by the
                      irradiation of a thin wire with single-beam Joule-class
                      short-pulse laser, a converging cylindrical shock is
                      generated compressing the wire material to conditions
                      relevant to the above applications. The shockwave was
                      observed using Phase Contrast Imaging employing a hard X-ray
                      Free Electron Laser with unprecedented temporal and spatial
                      sensitivity. The data collected for Cu wires is in agreement
                      with hydrodynamic simulations of an ablative shock launched
                      by highly impulsive and transient resistive heating of the
                      wire surface. The subsequent cylindrical shockwave travels
                      toward the wire axis and is predicted to reach a compression
                      factor of 9 and pressures above 800 Mbar. Simulations for
                      astrophysical relevant materials underline the potential of
                      this compression technique as a new tool for high energy
                      density studies at high repetition rates.},
      cin          = {FS-PETRA},
      ddc          = {500},
      cid          = {I:(DE-H253)FS-PETRA-20140814},
      pnm          = {632 - Materials – Quantum, Complex and Functional
                      Materials (POF4-632)},
      pid          = {G:(DE-HGF)POF4-632},
      experiment   = {EXP:(DE-H253)XFEL-SASE2-20150101},
      typ          = {PUB:(DE-HGF)16},
      pubmed       = {pmid:39266548},
      UT           = {WOS:001312845900035},
      doi          = {10.1038/s41467-024-52232-6},
      url          = {https://bib-pubdb1.desy.de/record/622084},
}