• DocumentCode
    1299689
  • Title

    Progress in Studying Scintillator Proportionality: Phenomenological Model

  • Author

    Bizarri, G. ; Cherepy, N.J. ; Choong, W.-S. ; Hull, G. ; Moses, W.W. ; Payne, S.A. ; Singh, J. ; Valentine, J.D. ; Vasilev, A.N. ; Williams, R.T.

  • Author_Institution
    Lawrence Berkeley Nat. Lab., Berkeley, CA, USA
  • Volume
    56
  • Issue
    4
  • fYear
    2009
  • Firstpage
    2313
  • Lastpage
    2320
  • Abstract
    We present a model to describe the origin of non-proportional dependence of scintillator light yield on the energy of an ionizing particle. The non-proportionality is discussed in terms of energy relaxation channels and their linear and non-linear dependences on the deposited energy. In this approach, the scintillation response is described as a function of the deposited energy deposition and the kinetic rates of each relaxation channel. This mathematical framework allows both a qualitative interpretation and a quantitative fitting representation of scintillation non-proportionality response as function of kinetic rates. This method was successfully applied to thallium doped sodium iodide measured with SLYNCI, a new facility using the Compton coincidence technique. Finally, attention is given to the physical meaning of the dominant relaxation channels, and to the potential causes responsible for the scintillation non-proportionality. We find that thallium doped sodium iodide behaves as if non-proportionality is due to competition between radiative recombinations and non-radiative Auger processes.
  • Keywords
    Compton effect; coincidence techniques; sodium compounds; solid scintillation detectors; thallium; Compton coincidence technique; NaI:Tl; SLYNCI; energy relaxation channels; ionizing particle; nonradiative Auger processes; radiative recombinations; scintillation nonproportionality; scintillator light yield; scintillator proportionality; thallium doped sodium iodide; Biomedical imaging; Contracts; Electrons; Energy resolution; Inspection; Ionizing radiation; Kinetic theory; Laboratories; Radiative recombination; Security; Auger process; NaI:Tl; density; proportionalityp; scintillation mechanism; scintillator;
  • fLanguage
    English
  • Journal_Title
    Nuclear Science, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    0018-9499
  • Type

    jour

  • DOI
    10.1109/TNS.2009.2022625
  • Filename
    5204677