Nuclear Engineering and Technology

Korean Nuclear Society (한국원자력학회)
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Analysis of alpha modes in multigroup diffusion

  • Sanchez, Richard (Department of Nuclear Engineering, Seoul National University) ;
  • Tomatis, Daniele (DEN, Service d'etudes des reacteurs et de mathematiques appliquees, CEA, Universite Paris-Saclay) ;
  • Zmijarevic, Igor (DEN, Service d'etudes des reacteurs et de mathematiques appliquees, CEA, Universite Paris-Saclay) ;
  • Joo, Han Gyu (Department of Nuclear Engineering, Seoul National University)
  • Received : 2017.06.02
  • Accepted : 2017.07.12
  • Published : 2017.09.25
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Abstract

The alpha eigenvalue problem in multigroup neutron diffusion is studied with particular attention to the theoretical analysis of the model. Contrary to previous literature results, the existence of eigenvalue and eigenflux clustering is investigated here without the simplification of a unique fissile isotope or a single emission spectrum. A discussion about the negative decay constants of the neutron precursors concentrations as potential eigenvalues is provided. An in-hour equation is derived by a perturbation approach recurring to the steady state adjoint and direct eigenvalue problems of the effective multiplication factor and is used to suggest proper detection criteria of flux clustering. In spite of the prior work, the in-hour equation results give a necessary and sufficient condition for the existence of the eigenvalue-eigenvector pair. A simplified asymptotic analysis is used to predict bands of accumulation of eigenvalues close to the negative decay constants of the precursors concentrations. The resolution of the problem in one-dimensional heterogeneous problems shows numerical evidence of the predicted clustering occurrences and also confirms previous theoretical analysis and numerical results.

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