Difference between revisions of "Radioactive decay source, practical example"

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The radioactive decay source mode is most conveniently used with burnup or activation calculation, in which case the radioactive material compositions can be read from a binary restart file (see the [[Input syntax manual#set rfw|set rfw]] and [[Input syntax manual#set rfr|set rfr]] options). In such case the same input can be used for both calculations without major modifications. Serpent converts the isotopic material compositions in the neutron transport calculation into elemental compositions for the following photon transport calculation, and source rate normalization is carried out automatically based on the total emission rate.
 
The radioactive decay source mode is most conveniently used with burnup or activation calculation, in which case the radioactive material compositions can be read from a binary restart file (see the [[Input syntax manual#set rfw|set rfw]] and [[Input syntax manual#set rfr|set rfr]] options). In such case the same input can be used for both calculations without major modifications. Serpent converts the isotopic material compositions in the neutron transport calculation into elemental compositions for the following photon transport calculation, and source rate normalization is carried out automatically based on the total emission rate.
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There are two sampling modes for selecting the position of emitted particles:
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#Analog sampling mode -- Source points are sampled uniformly throughout the geometry and each point accepted or rejected based on the ratio of local to maximum emission rate
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#Implicit sampling mode -- Source points are sampled uniformly throughout the geometry and the weight of the emitted photon adjusted according to the ratio of local to average emission rate.
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Efficiency of analog sampling may become poor when most (but not all) of the activity is concentrated on local hot spots. Implicit sampling allows covering the geometry uniformly with source points, but may
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lead to sparse distribution of weights and lead to problems with tally statistics.
  
 
The radioactive decay source mode has been tested in radiation shielding calculations involving a transport cask containing irradiated fuel and shut-down dose rate calculations for the ITER fusion reactor.<ref>Sirén, P. and Leppänen, J. ''"Expanding the Use of Serpent 2 to Fusion Applications: Development of a Plasma Neutron Source."'' In proc. PHYSOR 2016. Sun Valley, ID, May 1-6, 2016.</ref><ref>Leppänen, J. and Kaltiaisenaho, T. ''"Expanding the Use of Serpent 2 to Fusion Applications: Shut-down Dose Rate Calculations."'' In proc. PHYSOR 2016. Sun Valley, ID, May 1-6, 2016.</ref>
 
The radioactive decay source mode has been tested in radiation shielding calculations involving a transport cask containing irradiated fuel and shut-down dose rate calculations for the ITER fusion reactor.<ref>Sirén, P. and Leppänen, J. ''"Expanding the Use of Serpent 2 to Fusion Applications: Development of a Plasma Neutron Source."'' In proc. PHYSOR 2016. Sun Valley, ID, May 1-6, 2016.</ref><ref>Leppänen, J. and Kaltiaisenaho, T. ''"Expanding the Use of Serpent 2 to Fusion Applications: Shut-down Dose Rate Calculations."'' In proc. PHYSOR 2016. Sun Valley, ID, May 1-6, 2016.</ref>
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== Production of decay source from burnup calculation ==
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== Photon transport simulation using radioactive decay source ==
  
 
== References ==
 
== References ==
  
 
<references/>
 
<references/>

Revision as of 15:51, 24 April 2017

The radioactive decay source mode was implemented in Serpent 2.1.24 for the purpose of radiation transport calculations involving activated materials. The source term is determined by:

  • Isotopic material compositions, either user-defined or obtained from a previous burnup / activation calculation
  • Decay constants of radioactive nuclides read from ENDF format decay data file
  • Emission spectra read from ENDF format decay data file

The radiation types in version 2.1.28 and earlier are limited to discrete photon emitting reactions. Work on continuum reactions, neutron emission and bremsstrahlung from beta decay is under way.

The radioactive decay source mode is most conveniently used with burnup or activation calculation, in which case the radioactive material compositions can be read from a binary restart file (see the set rfw and set rfr options). In such case the same input can be used for both calculations without major modifications. Serpent converts the isotopic material compositions in the neutron transport calculation into elemental compositions for the following photon transport calculation, and source rate normalization is carried out automatically based on the total emission rate.

There are two sampling modes for selecting the position of emitted particles:

  1. Analog sampling mode -- Source points are sampled uniformly throughout the geometry and each point accepted or rejected based on the ratio of local to maximum emission rate
  2. Implicit sampling mode -- Source points are sampled uniformly throughout the geometry and the weight of the emitted photon adjusted according to the ratio of local to average emission rate.

Efficiency of analog sampling may become poor when most (but not all) of the activity is concentrated on local hot spots. Implicit sampling allows covering the geometry uniformly with source points, but may lead to sparse distribution of weights and lead to problems with tally statistics.

The radioactive decay source mode has been tested in radiation shielding calculations involving a transport cask containing irradiated fuel and shut-down dose rate calculations for the ITER fusion reactor.[1][2]

Production of decay source from burnup calculation

Photon transport simulation using radioactive decay source

References

  1. ^ Sirén, P. and Leppänen, J. "Expanding the Use of Serpent 2 to Fusion Applications: Development of a Plasma Neutron Source." In proc. PHYSOR 2016. Sun Valley, ID, May 1-6, 2016.
  2. ^ Leppänen, J. and Kaltiaisenaho, T. "Expanding the Use of Serpent 2 to Fusion Applications: Shut-down Dose Rate Calculations." In proc. PHYSOR 2016. Sun Valley, ID, May 1-6, 2016.