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@ARTICLE{Sjobak:465228,
      author       = {Sjobak, K. N. and Adli, E. and Corsini, R. and Farabolini,
                      W. and Boyle, Gregory James and Lindstroem, Carl Andreas and
                      Meisel, Martin and Osterhoff, Jens and Röckemann,
                      Jan-Hendrik and Schaper, Lucas and Dyson, A. E.},
      title        = {{S}trong focusing gradient in a linear active plasma lens},
      journal      = {Physical review accelerators and beams},
      volume       = {24},
      number       = {12},
      issn         = {1098-4402},
      address      = {College Park, MD},
      publisher    = {American Physical Society},
      reportid     = {PUBDB-2021-03811, arXiv:2012.10680},
      pages        = {121306},
      year         = {2021},
      note         = {arXiv title: Multi-kT/m Focusing Gradient in a Linear
                      Active Plasma Lens8 pages, 6 figures. Submitted to Physical
                      Review Applied},
      abstract     = {Active plasma lenses are compact devices developed as a
                      promising beam-focusing alternative for charged particle
                      beams, capable of short focal lengths for high-energy beams.
                      We have previously shown that linear magnetic fields with
                      gradients of around 0.3 kT/m can be achieved in argon-filled
                      plasma lenses that preserve beam emittance [C.A. Lindstrøm
                      et al., Phys. Rev. Lett. 121, 194801 (2018)]. Here we show
                      that with argon in a 500 μm diameter capillary, the fields
                      are still linear with a focusing gradient of 3.6 kT/m, which
                      is an order of magnitude higher than the gradients of
                      quadrupole magnets. The current pulses that generate the
                      magnetic field are provided by compact Marx banks, and are
                      highly repeatable. The demonstrated operation with
                      simultaneously high-gradient, linear fields and good
                      repeatability establish active plasma lenses as an ideal
                      device for pulsed particle beam applications requiring very
                      high focusing gradients that are uniform throughout the lens
                      aperture.},
      keywords     = {charged particle: beam (INSPIRE) / beam: width (INSPIRE) /
                      magnetic field: gradient (INSPIRE) / beam emittance
                      (INSPIRE) / beam focusing (INSPIRE) / beam: pulsed (INSPIRE)
                      / argon (INSPIRE) / accelerator: plasma (INSPIRE) / current:
                      time dependence (INSPIRE)},
      cin          = {FTX / MPA},
      ddc          = {530},
      cid          = {I:(DE-H253)FTX-20210408 / I:(DE-H253)MPA-20200816},
      pnm          = {621 - Accelerator Research and Development (POF4-621) /
                      VH-VI-503 - Plasma wakefield acceleration of highly
                      relativistic electrons with FLASH $(2015_IFV-VH-VI-503)$ /
                      ZT-0009 - Plasma Accelerators $(2018_ZT-0009)$},
      pid          = {G:(DE-HGF)POF4-621 / $G:(DE-HGF)2015_IFV-VH-VI-503$ /
                      $G:(DE-HGF)2018_ZT-0009$},
      experiment   = {EXP:(DE-MLZ)External-20140101},
      typ          = {PUB:(DE-HGF)16},
      eprint       = {2012.10680},
      howpublished = {arXiv:2012.10680},
      archivePrefix = {arXiv},
      SLACcitation = {$\%\%CITATION$ = $arXiv:2012.10680;\%\%$},
      UT           = {WOS:000739627800001},
      doi          = {10.1103/PhysRevAccelBeams.24.121306},
      url          = {https://bib-pubdb1.desy.de/record/465228},
}