Amanda Carreño scite author profile

Different spatial modes can be defined for the neutron diffusion equation such as the λ, α and γ-modes. These modes have been successfully used for the analysis of nuclear reactor characteristics. In this work, these modes are studied using a high order finite element method to discretize the equations and also different methods to solve the resulting algebraic eigenproblems, are compared. Particularly, Krylov subspace methods and block-Newton methods have been studied. The performance of these methods has been tested in several 3D benchmark problems: a homogeneous reactor and several configurations of NEACRP reactor.

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A Block Arnoldi Method for the SPN Equations

Vidal-Ferràndiz

Carreño

Ginestar

et al. 2019

International Journal of Computer Mathematics

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The simplified spherical harmonics equations are a useful approximation to the stationary neutron transport equation. The eigenvalue problem associated with them is a challenging problem from the computational point of view. In this work, we take advantage of the block structure of the involved matrices to propose the block inverse-free preconditioned Arnoldi method as an efficient method to solve this eigenvalue problem. For the spatial discretization, a continuous Galerkin finite element method implemented with a matrix-free technique is used to keep reasonable memory demands. A multilevel initialization using linear shape functions in the finite element method is proposed to improve the method convergence. This initialization only takes a small percentage of the total computational time. The proposed eigenvalue solver is compared to the standard power iteration method, the Krylov-Schur method and the generalized Davidson method. The numerical results show that it reduces the computational time to solve the eigenvalue problem. KEYWORDSGeneralized eigenvalue problem; Neutron transport, Multilevel method; Block inverse-free preconditioned Arnoldi method; Generalized Davidson Method.

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Multilevel method to compute the lambda modes of the neutron diffusion equation

Carreño

Vidal-Ferràndiz

Ginestar

et al. 2017

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Determination of the reactor kinetic characteristics is very important for the design and development of a new reactor system. In this sense, the computation of lambda modes associated to a nuclear power reactor has interest since these modes can be used to analyze the reactor criticality and to develop modal methods to analyze transient situations in the reactor. In this paper, the lambda problem has been discretized using a high order finite element method to obtain a generalized algebraic eigenvalue problem. A multilevel method is proposed to solve this generalized eigenvalue problem combining a hierarchy of meshes with a Modified Block Newton method. The Krylov-Schur method is used to compare the efficiency of the multilevel method solving several benchmark problems.

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Optimized Eigenvalue Solvers for the Neutron Transport Equation

Vidal-Ferràndiz

González-Pintor

Ginestar

et al. 2018

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Amanda Carreño

Block hybrid multilevel method to compute the dominant λ-modes of the neutron diffusion equation

Spatial modes for the neutron diffusion equation and their computation

A Block Arnoldi Method for the SPN Equations

Multilevel method to compute the lambda modes of the neutron diffusion equation

Optimized Eigenvalue Solvers for the Neutron Transport Equation

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