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@ARTICLE{Schtze:611194,
      author       = {Schütze, Paul and Abel, Aenne and Burkart, Florian and De
                      Silva, Malinda and Dinter, Hannes and Dojan, Kevin and
                      Herkert, Adrian and Jaster-Merz, Sonja Meike and
                      Kellermeier, Max and Kuropka, Willi and Mayet, Frank and
                      Ruiz Daza, Sara and Spannagel, Simon and Vinatier, Thomas
                      and Wennloef, Hakan Lennart Olov},
      title        = {electron{CT} - {A}n {I}maging {T}echnique {U}sing
                      {V}ery-high {E}nergy {E}lectrons},
      journal      = {Frontiers in physics},
      volume       = {12},
      issn         = {2296-424X},
      address      = {Lausanne},
      publisher    = {Frontiers Media},
      reportid     = {PUBDB-2024-04847},
      pages        = {1454854},
      year         = {2024},
      note         = {Also available from arXiv:
                      https://doi.org/10.48550/arXiv.2409.20091},
      abstract     = {The electronCT technique is an imaging method based on the
                      multiple Coulomb scattering of relativistic electrons and
                      has potential applications in medical and industrial
                      imaging. It utilizes a pencil beam of electrons in the very
                      high energy electron (VHEE, $50$-$250\,MeV$) range and a
                      single detection layer for the determination of the beam
                      profile. The technique constitutes a projectional,
                      two-dimensional imaging method and thus also qualifies for
                      the tomographic reconstruction of samples. Given the
                      simplicity of the technical setup and its location behind
                      the sample, the electronCT technique has potential synergies
                      with VHEE radiotherapy, making use of the same electron
                      source for both treatment and diagnostics and thus being a
                      candidate for in situ imaging and patient localization. At
                      the same time, several technical challenges arise from the
                      measurement technique when applied for the imaging of living
                      beings. Measurements performed at the ARES linear particle
                      accelerator at an electron energy of $155\,MeV$ using a
                      mouse phantom and a Timepix3 silicon pixel detector assembly
                      demonstrate the feasibility of this technique. Both
                      projectional and tomographic reconstructions are presented
                      and the potential and limits of the technology are
                      discussed.},
      cin          = {CMS / ATLAS / FTX / MPY1},
      ddc          = {530},
      cid          = {I:(DE-H253)CMS-20120731 / I:(DE-H253)ATLAS-20120731 /
                      I:(DE-H253)FTX-20210408 / I:(DE-H253)MPY1-20170908},
      pnm          = {611 - Fundamental Particles and Forces (POF4-611)},
      pid          = {G:(DE-HGF)POF4-611},
      experiment   = {EXP:(DE-H253)ARES-20200101},
      typ          = {PUB:(DE-HGF)16},
      UT           = {WOS:001357695000001},
      doi          = {10.3389/fphy.2024.1454854},
      url          = {https://bib-pubdb1.desy.de/record/611194},
}