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@ARTICLE{Jin:10240,
      author       = {Jin, F. and Yuan, S. and De Raedt, H. and Michielsen, K.
                      and Miyashita, S.},
      title        = {{C}orpuscular {M}odel of {T}wo-{B}eam {I}nterference and
                      {D}ouble-{S}lit {E}xperiments with {S}ingle {P}hotons},
      journal      = {Journal of the Physical Society of Japan},
      volume       = {79},
      issn         = {0031-9015},
      address      = {Tokyo},
      publisher    = {The Physical Society of Japan},
      reportid     = {PreJuSER-10240},
      pages        = {074401},
      year         = {2010},
      note         = {We would like to thank K. De Raedt, K. Keimpema, S. Zhao,
                      M. Novotny, and B. Baten for many helpful comments. This
                      work is partially supported by NCF, the Netherlands, by a
                      Grant-in-Aid for Scientific Research on Priority Areas, and
                      the Next Generation Super Computer Project, Nanoscience
                      Program from the Ministry of Education, Culture, Sports,
                      Science and Technology, Japan.},
      abstract     = {We introduce an event-based corpuscular simulation model
                      that reproduces the wave mechanical results of single-photon
                      double-slit and two-beam interference experiments and (of a
                      one-to-one copy of an experimental realization) of a
                      single-photon interference experiment with a Fresnel
                      biprism. The simulation comprises models that capture the
                      essential features of the apparatuses used in the
                      experiment, including the single-photon detectors recording
                      individual detector clicks. We demonstrate that
                      incorporating in the detector model, simple and minimalistic
                      processes mimicking the memory and threshold behavior of
                      single-photon detectors is sufficient to produce multipath
                      interference patterns. These multipath interference patterns
                      are built up by individual particles taking one single path
                      to the detector where they arrive one-by-one. The particles
                      in our model are not corpuscular in the standard, classical
                      physics sense in that they are information carriers that
                      exchange information with the apparatuses of the
                      experimental set-up. The interference pattern is the final,
                      collective outcome of the information exchanges of many
                      particles with these apparatuses. The interference patterns
                      are produced without making reference to the solution of a
                      wave equation and without introducing signalling or
                      non-local interactions between the particles or between
                      different detection points on the detector screen.},
      keywords     = {J (WoSType)},
      cin          = {JSC},
      ddc          = {530},
      cid          = {I:(DE-Juel1)JSC-20090406},
      pnm          = {Scientific Computing (FUEK411) / 411 - Computational
                      Science and Mathematical Methods (POF2-411)},
      pid          = {G:(DE-Juel1)FUEK411 / G:(DE-HGF)POF2-411},
      shelfmark    = {Physics, Multidisciplinary},
      typ          = {PUB:(DE-HGF)16},
      UT           = {WOS:000280096900022},
      doi          = {10.1143/JPSJ.79.074401},
      url          = {https://juser.fz-juelich.de/record/10240},
}