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A Variant of the Second-Moment Method for k-Eigenvalue Calculations

Connor Woodsford, James Tutt, Jim E. Morel

Nuclear Science and Engineering / Volume 198 / Number 11 / November 2024 / Pages 2148-2156

Research Article / dx.doi.org/10.1080/00295639.2024.2303107

Received:October 13, 2023
Accepted:December 25, 2023
Published:September 17, 2024

The second-moment (SM) method is a linear variant of the quasi-diffusion (QD) method for accelerating the iterative convergence of Sn source calculations. It has several significant advantages relative to the QD method, diffusion synthetic acceleration, and nonlinear diffusion acceleration. Here, we define a variant of this method for k-eigenvalue calculations that retains the advantages of the original method, and we computationally demonstrate the efficacy of the method for simple example calculations. In particular, this method has two important properties. First, it is a linear acceleration scheme requiring only the solution of a pure k-eigenvalue diffusion equation with a corrective source term as opposed to a k-eigenvalue drift-diffusion equation. Second, unconditional stability is achieved even when the diffusion equation is not discretized in a manner consistent with the Sn spatial discretization. We are unaware of any other scheme that has these properties. We also show a connection between our method and the k-eigenvalue acceleration technique of Barbu and Adams, which motivated us to develop our SM method.