Conditions for Translation and Scaling Invariance of the Neutron Diffusion Equation

TL;DR

This paper uses Lie group methods to identify conditions under which the neutron diffusion equation exhibits translation and scaling invariance, providing analytic forms of material properties that preserve these symmetries.

Contribution

It introduces an exterior differential system approach for symmetry analysis of the neutron diffusion equation, deriving material property functions that maintain specific symmetries.

Findings

Derived material functions enabling translation and scaling symmetries.

Generalized existing symmetry results in neutron diffusion literature.

Provided a framework for future symmetry analyses of neutron transport models.

Abstract

Lie group methods are applied to the time-dependent, monoenergetic neutron diffusion equation in materials with spatial and time dependence. To accomplish this objective, the underlying 2nd order partial differential equation (PDE) is recast as an exterior differential system so as to leverage the isovector symmetry analysis approach. Some of the advantages of this method as compared to traditional symmetry analysis approaches are revealed through its use in the context of a 2nd order PDE. In this context, various material properties appearing in the mathematical model (e.g., a diffusion coefficient and macroscopic cross section data) are left as arbitrary functions of space and time. The symmetry analysis that follows is restricted to a search for translation and scaling symmetries; consequently the Lie derivative yields specific material conditions that must be satisfied in order to maintain the presence of these important similarity transformations. The principal outcome of this work is thus the determination of analytic material property functions that enable the presence of various translation and scaling symmetries within the time- dependent, monoenergetic neutron diffusion equation. The results of this exercise encapsulate and generalize many existing results already appearing in the literature. While the results contained in this work are primarily useful as phenomenological guides pertaining to the symmetry behavior of the neutron diffusion equation under certain assumptions, they may eventually be useful in the construction of exact solutions to the underlying mathematical model. The results of this work are also useful as a starting point or framework for future symmetry analysis studies pertaining to the neutron transport equation and its many surrogates.