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@MASTERSTHESIS{Schuetz:220092,
      author       = {Schuetz, Anne},
      title        = {{S}imulation of {P}article {F}luxes at the {DESY}-{II}
                      {T}est {B}eam {F}acility},
      issn         = {1435-8085},
      school       = {Karlsruher Institut für Technologie (KIT)},
      type         = {MS},
      publisher    = {Verlag Deutsches Elektronen-Synchrotron},
      reportid     = {PUBDB-2015-02099, DESY-THESIS-2015-017},
      series       = {DESY-THESIS},
      pages        = {100},
      year         = {2015},
      note         = {Karlsruher Institut für Technologie (KIT), Masterarbeit,
                      2015},
      abstract     = {In the course of this Master's thesis "Simulation of
                      Particle Fluxes at the DESY-II Test Beam Facility'' the test
                      beam generation for the DESY test beam line was studied in
                      detail and simulated with the simulation software SLIC. SLIC
                      uses the Geant4 toolkit for realistic Monte Carlo
                      simulations of particles passing through detector
                      material.After discussing the physics processes relevant for
                      the test beam generation and the principles of the beam
                      generation itself, the software used is introduced together
                      with a description of the functionality of the Geant4 Monte
                      Carlo simulation. The simulation of the test beam line
                      follows the sequence of the test beam generation. Therefore,
                      it starts with the simulation of the beam bunch of the
                      synchrotron accelerator DESY-II, and proceeds step by step
                      with the single test beam line components. An additional
                      benefit of this thesis is the provision of particle flux and
                      trajectory maps, which make fluxes directly visible by
                      following the particle tracks through the simulated beam
                      line. These maps allow us to see each of the test beam line
                      components, because flux rates and directions change rapidly
                      at these points. They will also guide the decision for
                      placements of future test beam line components and
                      measurement equipment.In the end, the beam energy and its
                      spread, and the beam rate of the final test beam in the test
                      beam area were studied in the simulation, so that the
                      results can be compared to the measured beam parameters. The
                      test beam simulation of this Master's thesis will serve as a
                      key input for future test beam line improvements.},
      keywords     = {Unveröffentlichte Hochschulschrift (GND)},
      cin          = {FHTestBeam},
      cid          = {I:(DE-H253)FHTestBeam-20150203},
      pnm          = {631 - Accelerator R $\&$ D (POF3-631)},
      pid          = {G:(DE-HGF)POF3-631},
      experiment   = {EXP:(DE-H253)TestBeamline21-20150101},
      typ          = {PUB:(DE-HGF)29 / PUB:(DE-HGF)19},
      doi          = {10.3204/DESY-THESIS-2015-017},
      url          = {https://bib-pubdb1.desy.de/record/220092},
}